Global traffic management system using ip anycast routing and dynamic load-balancing

ABSTRACT

A method and apparatus for serving content requests using global and local load balancing techniques is provided. Web site content is cached using two or more point of presences (POPs), wherein each POP has at least one DNS server. Each DNS server is associated with the same anycast IP address. A domain name resolution request is transmitted to the POP in closest network proximity for resolution based on the anycast IP address. Once the domain name resolution request is received at a particular POP, local load balancing techniques are performed to dynamically select the appropriate Web server at the POP for use in resolving the domain name resolution request. Approaches are described for handling bursts of traffic at a particular POP, security, and recovering from the failure of various components of the system.

RELATED APPLICATION DATA

This application is a continuation of U.S. patent application Ser. No. 11/040,167 filed Jan. 19, 2005 which is incorporated herein by reference as if fully set forth herein, under 35 U.S.C. §120, which claims priority to Provisional U.S. Patent Application No. 60/627,798 (Attorney Docket No. 60095-0063), filed on Oct. 29, 2004, which is incorporated by reference, and is also a continuation-in-part of U.S. patent application Ser. No. 10/873,570, filed Jun. 21, 2004, which is a continuation of U.S. patent application Ser. No. 09/909,651, filed Jul. 19, 2001, which is a continuation-in-part of U.S. patent application Ser. No. 09/641,746, filed Aug. 18, 2000, and claims priority to Provisional U.S. Patent Application Nos. 60/219,172, 60/219,166, 60/219,946, and 60/219,177, all of which were filed on Jul. 19, 2000, and U.S. patent application Ser. No. 09/644,927, filed Aug. 23, 2000, the entire disclosures of which are hereby incorporated by reference as if fully set forth herein.

FIELD OF THE INVENTION

The present invention relates to delivering content and dynamic load balancing across a network.

BACKGROUND

The Internet is a world wide “super-network” which connects together millions of individual computer networks and computers. The Internet is generally not a single entity. It is an extremely diffuse and complex system over where no single entity has complete authority or control. Although the Internet is widely know for one of its ways of presenting information through the World Wide Web (herein “Web”), there are many other services currently available based upon the general Internet protocols and infrastructure.

The Web is often easy to use for people inexperienced with computers. Information on the Web often is presented on “pages” of graphics and text that contain “links” to other pages either within the same set of data files (i.e., Web site) or within data files located on other computer networks. Users often access information on the Web using a “browser” program such as one made by Netscape Communications Corporation (now America Online, Inc.) of Mountain View, Calif. or Explorer™ from Microsoft Corporation of Redmond, Wash. Browser programs can process information from Web sites and display the information using graphics, text, sound, and animation. Accordingly, the Web has become a popular medium for advertising goods and services directly to consumers.

As time progressed, usage of the Internet has exploded. There are literally millions of users on the Internet. Usage of the Internet is increasing daily and will eventually be in the billions of users. As usage increases so does traffic on the Internet. Traffic generally refers to the transfer of information from a Web site at a server computer to a user at a client computer. The traffic generally travels through the worldwide network of computers using a packetized communication protocol, such as TCP/IP. Tiny packets of information travel from the server computer through the network to the client computer. Like automobiles during “rush hour” on Highway 101 in Silicon Valley, the tiny packets of information traveling through the Internet become congested. Here, traffic jams which cause a delay in the information from the server to the client occur during high usage hours on the Internet. These traffic jams lead to long wait times at the client location. Here, a user of the client computer may wait for a long time for a graphical object to load onto his/her computer.

A user of a Web browser may request content, such as a Web page, by submitting to the Web browser a Uniform Resource Locator (URL) that identifies the requested content. The submitted URL includes a host name (e.g., www.customer.com). While Web servers use IP addresses to identify one another, it is easier for humans to use a host name to identify a Web server, as a host name is usually expressed in words and/or characters, as opposed to a string of numbers as in an IP address.

After a user submits a URL to a Web browser, the Web browser determines the IP address associated with the host name that can provide the requested content by transmitting, to a client domain name server, a request to resolve the host name entry contained within the URL. For example, the request to resolve the host name entry may be implemented by using the gethostbyname function of the Windows Sockets 2 protocol. After the Web browser receives the IP address of the host name identified in the URL from the client domain name server, the Web browser transmits a content request to the Web server associated with the newly obtained IP address to obtain the requested content.

The client domain name server obtains the IP address of the host name by issuing a domain name resolution request to one or more entities, such as a root domain name server. A domain name resolution request is a request to translate a domain name into an IP address associated with a Web server. Load-balancing techniques may be employed when resolving the domain name resolution request to minimize the amount of time spent processing content requests from the client issuing the domain name resolution request. Load-balancing involves distributing processing and communications activity evenly across a network so that no single component in the network is overwhelmed. For example, Web sites that receive large amounts of traffic often employ two or more Web servers in a load-balancing scheme. If one Web server becomes overloaded, requests may be forwarded to another Web server with more capacity.

Load-balancing may be performed within a particular point of presence (POP). A POP refers to one or more Web servers and associated components, typically operating as a functional unit, that are each capable of serving content across the WWW. A Web site may be implemented using several POPs, each operating in a different geographical location, to increase the likelihood that a Web browser requesting content from the Web site is in close network proximity to a POP of that Web site. When load-balancing is performed within a particular POP, it is referred to as local load-balancing. When load-balancing is performed across multiple POPs, it is referred to as global load-balancing.

An improved way to transfer information over a network is highly desirable. It would be advantageous to provide content delivery and global traffic management network system that allows network traffic to be efficiently distributed to content servers in any POP using global and local load-balancing techniques without incurring the disadvantages of the approaches discussed above. The approaches described in this section are approaches that could be pursued, but not necessarily approaches that have been previously conceived or pursued. Therefore, unless otherwise indicated, it should not be assumed that any of the approaches described in this section qualify as prior art merely by virtue of their inclusion in this section.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the present invention are illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings and in which like reference numerals refer to similar elements and in which:

FIG. 1 is a simplified diagram of a system according to an embodiment of the present invention;

FIG. 2 is a more detailed diagram of probes used in the system according to an embodiment of the present invention;

FIG. 3 is a more detailed diagram of a caching sequence used in the system according to an embodiment of the present invention;

FIG. 4 is a simplified flow diagrams of methods according to embodiments of the present invention;

FIG. 4A is a simplified system diagram according to an embodiment of the present invention;

FIGS. 5A to 5H are simplified diagrams of content delivery network according to an embodiment of the present invention;

FIGS. 6A to 6E are simplified diagrams of global traffic management system according to an embodiment of the present invention;

FIG. 7 is a block schematic diagram showing the interaction between the Speedera DNS Server (SPD) and other components according to the invention;

FIG. 8 is a block schematic diagram showing a POP Speedera network with the invention's software components distributed among POP servers and Network Operations Centers according to the invention;

FIG. 9 is a block schematic diagram showing the interaction between software components of the invention according to the invention;

FIG. 10 is a block schematic diagram showing the exchange of data between Latency Probes, Service Probes and other servers within a network according to the invention;

FIG. 11 is a block schematic diagram showing the processes and exchange of data between logging server components according to the invention;

FIG. 12A is block diagram of an illustrative network performing local load-balancing according to a first approach;

FIG. 12B is a block diagram of an illustrative network performing local load-balancing according to a second approach;

FIG. 13 is a block diagram of an illustrative network performing global load-balancing across multiple POPs according to an approach;

FIG. 14 is a block diagram of a system according to an embodiment of the invention;

FIG. 15 is a flowchart illustrating the functional steps of a Web browser requesting content according to an embodiment of the invention;

FIG. 16 is a flowchart illustrating the functional steps of handling traffic bursts according to an embodiment of the invention;

FIG. 17 is a block diagram of a POP configured to recover using a load balancer according to an embodiment of the invention;

FIG. 18 is a block diagram of a system configured to recover form the failure of all POP DNS servers at a POP according to an embodiment of the invention; and

FIG. 19 is a block diagram that illustrates a computer system upon which an embodiment of the invention may be implemented.

DETAILED DESCRIPTION

In the following description, for the purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of embodiments of the present invention. It will be apparent, however, that embodiments of the present invention may be practiced without these specific details. In other instances, well-known structures and devices are shown in block diagram form in order to avoid unnecessarily obscuring the embodiments of the present invention described herein.

Functional Overview

An approach for a system for global traffic management with dynamic load balancing is presented. Embodiments of the invention perform both global load-balancing and local load-balancing. Specifically, embodiments of the invention advantageously allow domain name resolution requests to be load balanced across all point of presences (POPs) of the system. A domain name resolution request is transmitted to a particular POP that is closest in network proximity to the client domain name server. That POP performs local load balancing techniques to dynamically select the appropriate Web server (“the selected Web server”) for use in resolving the domain name resolution request.

Embodiments of the invention advantageously employ the IPv6 protocol to perform global load balancing using the anycast feature. IPv6 is a protocol by the Internet Engineering Task Force (IETF) that describes how to specify Internet packets. IPv6 includes an anycast feature that allows one to specify an anycast address (such as an IP address) that identifies multiple interfaces. With the appropriate unicast routing topology, packets addressed to an anycast address are delivered to a single interface, e.g., the nearest interface that is identified by the address. The nearest interface is defined as being the closest in terms of routing distance. A multicast address is used for one-to-many communication, with delivery to multiple interfaces. An anycast address is used for one-to-one-of-many communication, with delivery to a single interface.

Embodiments may use the anycast feature of IPv6 to associate an identical IP address with a group of domain name servers (individually referred to as a “POP DNS server”) located at one or more POPs of the system. For example, the identical IP address may be assigned to each POP DNS server in every POP implementing a Web site in an embodiment.

When a Web browser transmits a request to resolve a host name entry to a client domain name server, the client domain name server may determine how to resolve the request with greater ease using embodiments of the invention. The client domain name server is configured to determine the shortest route to any IP address. In this way, since each POP DNS server at each POP is assigned an identical IP address, the client domain name server can determine the shortest route to any POP DNS server in any POP since each POP DNS server is assigned the same IP address. From the perspective of the client domain name server, each of the POP DNS servers in each POP are the same domain name server, so the client domain name server can determine the POP DNS server that is closest in network proximity to the client domain name server.

The client domain name server transmits the domain name resolution request to a POP DNS that is closest in network proximity. The POP DNS server determines which Web server at the selected POP should be used to resolve the domain name resolution request using local load balancing techniques.

Embodiments of the invention provide efficient techniques for performing global and local load-balancing, while eliminating the possibility that traffic will oscillate between different POPs of the system. Embodiments of the invention are configured to handle situations of normal traffic and high burst of traffic, as well as helping prevent the system from an attack from a hostile external entity by minimizing exposure of the system to the attack. Embodiments of the invention also are configured to automatically recover from the failure of one or more components of the system.

Techniques for Performing Load Balancing

Techniques for performing load balancing, according to an embodiment of the invention, shall now be presented. As described herein, embodiments of the invention comprise a content delivery and global traffic management network system that provides a plurality of caching servers connected to a network. The caching servers host customer content that can be cached and stored, and respond to requests for Web content from clients. If the requested content does not exist in memory or on disk, it generates a request to an origin site to obtain the content. A DNS Server (SPD) load balances network requests among customer Web servers and directs client requests for hosted customer content to the appropriate caching server which is selected by choosing the caching server that is closest to the user, is available, and is the least loaded.

Embodiments discussed herein are described with reference to a POP domain name server (POP DNS server). As described herein, a POP DNS server may be implemented by a SPD.

SPD also supports persistence and returns the same IP addresses, for a given client. The entire Internet address space is broken up into multiple zones. Each zone is assigned to a group of SPD servers. If an SPD server gets a request from a client that is not in the zone assigned to that SPD server, it forwards the request to the SPD server assigned to that zone. Servers write information about the content delivered to log files that are picked up by a log server.

The invention is embodied in a content delivery and global traffic management network system in a computer environment. A system according to the invention provides efficiently distributed network traffic to content servers by load balancing requests among servers and provides cached content for faster response times. In addition, the invention provides traffic and server information gathering for up to date system status.

A technique including a user interface device and system for global traffic management and content distribution is provided. In an exemplary embodiment, the method is applied to a world wide network of computers, such as the Internet or an internet.

In a specific embodiment, the invention provides a user interface device and system for providing a shared GTM and CDN (collectively Universal Distribution Network) for a service fee, where the customer or user does not need to purchase significant hardware and/or software features. The present interface device and system allows a customer to scale up its Web site, without a need for expensive and difficult to use hardware and/or software. In a preferred embodiment, the customer merely pays for a service fee, which can be fixed, variable, lump sum, or based upon a subscription model using the present system. The present device and system are preferably implemented on a system including a novel combination of global traffic management and content distribution.

An overall system diagram 100 is illustrated in FIG. 1. The diagram is merely an example, which should not unduly limit the scope of the claims herein. One of ordinary skill in the art would recognize many other variations, modifications, and alternatives. As shown, the system 100 includes a variety of features to defined the Universal Delivery Network (UDN). The UDN has a combined content delivery network 103 and 104 and a global traffic management network 105, which are coupled to each other. This eliminates the need for independent CDN and GTM solutions. The UDN can be implemented as a single outsourced solution or service to a customer. When deployed across the WAN, it creates a unified network that provides a universal solution for content routing and high availability delivery.

Customers can leverage the size, scope, and location of the UDN to store content such as HTML, images, video, sound and software for fast and highly available access by clients. The network can also incorporate customer origin sites 107, 109 that will then benefit from shared load balancing and traffic management. Customers with generated content, such as search engines, auctions and shopping carts, can use the latter feature to add their own content servers to the network. In some embodiments, the system typically requires no software or hardware to be installed or run at a customer site. A Web interface is available for display of the network's current status as well as historical statistics on a per customer basis.

The system functions by mapping hostnames, such as www.customer.com to a customers origin servers 107 and 109. The local DNS 113 queries the traffic management system 105 for name resolution of the customers Web site and receives a response specifying the server best suited to handle the request, either customer origin servers 107 or servers 103 located in the UDN. When the client 111 requests a customer homepage, tags within the HTML direct the imbedded static content to the network of cache servers 103 and 104. In this example the static content may be tagged with a domain name like customer.speedera.com. Each local DNS in the example is directed to a different resource for each hostname based on several factors, such as proximity to the resource, network congestion, and server load.

In this example, www.customer.com is mapped to the customer origin servers represented by customer origin Sites 1 109 and 2 107. Customer.speedera.net is mapped to a collection of delivery nodes represented by point of presence servers, i.e., POPs 103, 104. As merely an example, a method for using such a UDN is provided below.

-   1. The client 111 requests a customer home page: www.customer.com     from a local DNS 113. -   2. The local DNS 113 queries the traffic management system 105 for     name and address resolution and receives a reply 125, 127 indicating     the optimal customer origin site to retrieve the homepage 131. In     this step, the traffic management system still looks at many if not     all factors; network health, server health, packet loss, cost, etc.     to determine the optimal customer origin site. -   3. The client connects to the site and retrieves the home page     (solid blue line) 123, 121. -   4. An object with the image tag specifying     http://customer.speedera.net/www.customer.com/hello.gif is found in     the HTML of the homepage. -   5. The local DNS queries the traffic management system for name and     address resolution. -   6. The traffic management system looks 129, 131 at factors such as     network performance and server load and returns the address of the     POP best suited to serve the requested content. -   7. The client then retrieves the content from the specified delivery     node 117, 119.

This sequence of steps is merely illustrative. The steps can be performed using computer software or hardware or a combination of hardware and software. Any of the above steps can also be separated or be combined, depending upon the embodiment. In some cases, the steps can also be changed in order without limiting the scope of the invention claimed herein. One of ordinary skill in the art would recognize many other variations, modifications, and alternatives. Details of each of the features noted above are more fully described below.

The DNS server (DNS) can be thought of as the traffic director of the system. It contains a mapping of where resources (grouped by hostnames) have been allocated as well as the current state of each resource and their availability to each client. It receives the static information (the mappings) from the configuration file and the dynamic information (resource availability) from the probes. The configuration file also instructs the DNS server how to weight the various criteria available when making its decisions. The DNS is a fully functional DNS server and is compatible with current versions of BIND. Decision criteria cover such areas as resource availability, resource load, latency, static mapping configuration, persistence requirements, fail over logic, weighting parameters, and others, each of which can be alone or combined.

Multiple DNS servers are deployed to provide high availability. The DNS servers are spread throughout the network to avoid single points of failure. The DNS server was designed from the beginning with the ability to proxy requests. This proxy ability combined with algorithms to divide client latency and persistence information across a group of DNS servers greatly reduces the problems associated with WAN replication and synchronization. In the event a request arrives at a DNS server that is not authoritative for this client, the DNS can proxy the request to any number of servers to find an authoritative answer.

The DNS server logs both request and operational data to the database for subsequent viewing. Both real-time and historical views are available. The request data allows the administrator and customer to see to the number of requests directed to each POP on a per hostname basis. The operational data provides statistics about the DNS server and would typically only be viewed by the administrator.

The present system also uses one or more probes to detect information about certain criteria from the network. There are probes including a NetProbes, a ServiceProbe and a LatencyProbe. ServiceProbes test local server resources while LatencyProbes conduct network round trip tests to clients. Each POP in the network is assigned a ServiceProbe and a LatencyProbe—these can be separate machines but in most cases, the same machine will perform both types of probe.

The NetProbes are responsible for providing the traffic management system with service and latency metrics. The metrics are reported to the DNS server and LogServers. FIG. 2 is a simplified diagram 200 of these probes according to embodiments of the present invention. This diagram is merely an example which should not limit the scope of the claims herein. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. The diagram 200 includes a POP 201, which includes a NetProbes server. Service probes monitor the POP servers to test the availability and load of the services they support. The latency probe tests the round trip time between the POP and the DNS servers.

A ServiceProbe determines service metric information for servers in the UDN and reports them to the DNS server. Service metrics are one of the decision criteria used by the DNS to make its routing determinations. Each server in the UDN supports one or more services—a Web server provides HTTP service, a FTP server provides FTP service. The service probe uses various approaches for gathering data—a service test and statistical monitoring. The value of a service metric is dependent on the metric type and its implementation.

The HTTP service is an example of the service test approach. Rather then try to test the individual characteristics of a server that may have an impact on performance, the service itself is evaluated as a user would experience it, in order to determine its response time and validity. LOADP, a process running on each server, is implemented as a statistical monitor and is used as a generic service for testing purposes. LOADP provides direct measurement of many system parameters including CPU load, memory usage, swap and disk status, and is used in load balancing decisions.

Hostnames in the system are mapped to service types. This allows a given server to support multiple services and be evaluated independently for each of them. When a request for a particular hostname arrives at a DNS, the service associated with that hostname is compared on each of the machines to find the best-suited server. The data from the probes are sent to both the DNS as well as the database. By sending the data to the database, it allows the performance of the network to be viewed in real time as well as over a period of time.

Every server in the UDN is housed in a POP and each POP has a Latency Probe assigned to it, as shown. The Latency Probes determine the latency from their location to other locations on the Internet (specifically to client DNS' requesting name resolution). The DNS' use this information in determining the best-suited server for a particular request. The list of locations that are used in order to determine the latency is driven by the DNS. When it is determined by a DNS server that its current information regarding latency between “x” number of POPs and a client's local DNS has become stale, it will instruct the probe for that particular POP to recalculate the latency.

The probes utilize a collection of methods to determine the latency based on cost. The probe uses the least expensive method first and moves on to more expensive methods if no results are determined. The probe is designed so new methods can be plugged in as they are developed. The methods can be either active or passive and are prioritized based on accuracy. Active methods may take the form of ping or traceroute but are typically more sophisticated. Passive methods could reference local BGP tables to determine cost metrics.

The individual latency data is sent to the DNS servers while operational data of each method, their success rates, etc are sent to the database. This allows the current and new methods to be monitored and managed. LatencyProbes perform latency tests to the local client DNS (LDNS). The LatencyProbes build a table of LDNS' to test over time, receiving the list of which DNS client IP addresses to probe from the DNS Servers in the network.

In a specific embodiment, the delivery nodes are the edge delivery servers of the network. The invention can support any types of IP based delivery servers including but not limited to HTTP, SSL, FTP, Streaming, NNTP, and DNS servers. In preferred embodiments, the invention uses an HTTP server and SSL cache server. The HTTP and SSL servers are identical with the exception of the encryption used on the data to and from the SSL cache in some embodiments. These servers have a proxy component that allows them to fill their cache by making requests to an origin site if a requested object is not in the cache. A method according to the invention can be briefly described as follows in reference to the simplified diagram 300 of FIG. 3:

-   1. An initial user makes a request to the cache for an object     http://customer.speedera.net/www.customer.com/images/test.gif (Step     1); -   2. The cache, discovering that it does not have the object, will     find the name of the origin site in the URL (www.customer.com) and     make a request to the origin site for /images/test.gif (Step 2); -   3. When the cache receives the object it is saved on disk and memory     and returned to the initial user. Subsequent users who make requests     for the same object will be satisfied by the cache directly (Step     3).

This sequence of steps is merely illustrative. The steps can be performed using computer software or hardware or a combination of hardware and software. Any of the above steps can also be separated or be combined, depending upon the embodiment. In some cases, the steps can also be changed in order without limiting the scope of the invention claimed herein. One of ordinary skill in the art would recognize many other variations, modifications, and alternatives.

Other protocols will work in a similar fashion unless there is a time concern with loading the first request. An example of this is a live streaming event or large file downloads (patches or video on demand). In these cases the caches may be pre-filled with the data that they need to serve. This pre-filling may take place over terrestrial lines or via satellite in some cases. Statistics about data delivered from the delivery nodes are reported through the logging system to the database for subsequent viewing and analysis.

The system also has a user interface. Here, engineering staff as well as customers can login to monitor and administer the network access from nearly any Internet connected Web browser (with proper authentication). The user interface includes tables and graphs from the database. Data arrives at the user interface through the Logging System. This system has two parts: Log Distributor daemons and Log Collector daemons. This daemon monitors a defined directory for completed log files. Log files are defined as complete when they reach a defined size or age. A logging API which all resources share controls the definitions of size and age. When the Log Distributor finds completed log files it is able to send them back to one of many Log Collector daemons for insertion in the database.

As noted, the present network has many advantages. The network has as comprehensive, extensible, multi-faceted global traffic management system as its core, which is coupled to a content delivery network. Further details of the present content delivery network and global traffic management device are provided below. According to the present invention, a method for providing service to customers is provided. Details of such service are provided below.

FIG. 4 is a simplified flow diagram of a novel service method 400 according to an embodiment of the present invention. The diagram is merely an example, which should not unduly limit the scope of the claims herein. One of ordinary skill in the art would recognize many other variations, modifications, and alternatives. As shown, the method begins at start, step 401. The method connects (step 403) a client to a server location through a world wide network of computers. The world wide network of computers can include an internet, the Internet, and others. The connection occurs via a common protocol such as TCP/IP. The client location is coupled to a server, which is for a specific user. The user can be any Web site or the like that distributes content over the network. As merely an example, the user can be a portal such as Yahoo! Inc. Alternatively, the user can be an electronic commerce site such as Amazon.com and others. Further, the user can be a health site. Information sites include the U.S. Patent Office Web site, educational sites, financial sites, adult entertainment sites, service sites, business to business commerce sites, etc. There are many other types of users that desire to have content distributed in an efficient manner.

In a specific embodiment, the user registers its site on the server, which is coupled to a content distribution server coupled to a global traffic management server. The user registers to select (step 407) a service from the server. The service can be either a traffic management service (step 414) or a traffic management service and content distribution service (step 411). Depending upon the embodiment, the user can select either one and does not need to purchase the capital equipment required for either service. Here, the user merely registers for the service and pays a service fee. The service fee can be based upon a periodic time frequency or other parameter, such as performance, etc. Once the service has been requested, the user performs some of the steps noted herein to use the service.

Next, the method processes (step 423) the user's request and allows the user to use the content distribution network and/or global traffic management network, where the user's Web pages are archives and distributed through the content distribution network in the manner indicated herein. The user's Web site should become more efficient from the use of such networks. Once a periodic time frequency or other frequency has lapsed (step 419), the method goes to an invoicing step, step 417. The invoicing step sends (step 427) an invoice to the user. Alternatively, the process continues until the periodic time frequency for the designated service lapses via line 422. The invoice can be sent via U.S. mail, electronic mail, or the like. The method stops, step 425. Alternatively, the invoicing step can deduct monetary consideration through an electronic card, e.g., debit card, credit card.

This sequence of steps is merely illustrative. The steps can be performed using computer software or hardware or a combination of hardware and software. Any of the above steps can also be separated or be combined, depending upon the embodiment. In some cases, the steps can also be changed in order without limiting the scope of the invention claimed herein. One of ordinary skill in the art would recognize many other variations, modifications, and alternatives. It is also understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit and purview of this application and scope of the appended claims.

FIG. 4A is a simplified diagram of a computing system 430 according to an embodiment of the present invention. This diagram is merely an example which should not unduly limit the scope of the claims herein. One of ordinary skill in the art would recognize many other variations, modifications, and alternatives. Like reference numerals are used in this FIG., as the previous FIG. for cross-referencing purposes only. As shown, the computing system 430 carries out certain functionality that is integrated into the method above as well as others. The computing system includes an accounting module 429, which carries out certain accounting functions. The accounting module interfaces with mass memory storage 431, a microprocessing device 433, and a network interface device 435, which couples to local and/or wide area networks. The module oversees an invoicing step 417 and transfer step 427, as shown. Here, the accounting module is a task master for the service based method for using the content delivery network and/or global traffic management network.

Before discussing the accounting module in detail, we begin an overall method at start, step 401. The method connects (step 403) a client to a server location through a world wide network of computers. The world wide network of computers can include an internet, the Internet, and others. The connection occurs via a common protocol such as TCP/IP. The client location is coupled to a server, which is for a specific user. The user can be any Web site or the like that distributes content over the network. As merely an example, the user can be a portal such as Yahoo! Inc. Alternatively, the user can be an electronic commerce site such as Amazon.com and others. Further, the user can be a health site. Information sites include the U.S. Patent Office Web site, educational sites, financial sites, adult entertainment sites, service sites, business to business commerce sites, etc. There are many other types of users that desire to have content distributed in an efficient manner.

In a specific embodiment, the user registers its site on the server, which is coupled to a content distribution server coupled to a global traffic management server. The user registers to select (step 407) a service from the server. The service can be either a traffic management service (step 414) or a traffic management service and content distribution service (step 411). Depending upon the embodiment, the user can select either one and does not need to purchase the capital equipment required for either service. Here, the user merely registers for the service and pays a service fee. The service fee can be based upon a periodic time frequency or other parameter, such as performance, etc. Additionally, the user enters information such as the user's domain name, physical address, contact name, billing and invoicing instructions, and the like. Once the service has been requested, the user performs some of the steps noted herein to use the service.

Next, the method processes (step 423) the user's request and allows the user to use the content distribution network and/or global traffic management network, where the user's Web pages are archives and distributed through the content distribution network in the manner indicated herein. The user's Web site should become more efficient from the use of such networks. Once a periodic time frequency or other frequency has lapsed (step 419), the method goes to an invoicing step, step 417. Here, the method accesses the accounting module, which can retrieve registration information about the user, service terms, invoices, accounts receivables, and other information, but is not limited to this information. The accounting module determines the service terms for the user, which has already registered. Once the service terms have been uncovered from memory, the module determines the way the user would like its invoice. The accounting module directs an invoicing step, which sends (step 427) an invoice to the user. Alternatively, the process continues until the periodic time frequency for the designated service lapses via line 422. The invoice can be sent via U.S. mail, electronic mail, or the like. The method stops, step 425. Alternatively, the invoicing step can deduct monetary consideration through an electronic card, e.g., debit card, credit card. To finalize the transaction, an electronic mail message can be sent to the user, which is logged in memory of the accounting module.

This sequence of steps is merely illustrative. The steps can be performed using computer software or hardware or a combination of hardware and software. Any of the above steps can also be separated or be combined, depending upon the embodiment. In some cases, the steps can also be changed in order without limiting the scope of the invention claimed herein. One of ordinary skill in the art would recognize many other variations, modifications, and alternatives. It is also understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit and purview of this application and scope of the appended claims.

EXAMPLE

To prove the principle and operation of the present invention, we have provided examples of a user's experience using the present invention. These examples are merely for illustration and should not unduly limit the scope of the claims herein. One of ordinary skill in the art would recognize many other variations, modifications, and alternatives. For easy reading, we have provided a description for a user's experience of a content delivery network and a user's experience of a global traffic management service, which is coupled to such content delivery network.

Content Delivery Network 1. Overview

In a specific embodiment, the invention provides a content distribution network. The following description contains information on how to use a graphical user interface to monitor activity, control cache, and perform checks. In some embodiments, the invention also provides a way for customer feedback to improve the service.

The present network is substantially always available in preferred embodiments. The network includes a Network Operations Center (NOC), which is dedicated to maintaining the highest possible network availability and performance. In most cases, the network is supported and staffed by specially trained service engineers, the 24-hour, 7 day NOC provides consultation, troubleshooting, and solutions for every issue. The staff can be reached through telephone, email, fax, or online. The staff generally connects you to engineers and solutions, not to answering machines.

In a specific embodiment, the network service can be used as long as the user has certain desires. For example, the user has content that needs to be delivered to end-users. This content can be delivered through HTTP, HTTPS, Streaming Media, or FTP, and the like. The server is for hosting the content on the Internet. For standard Web content, we implemented a caching system to distribute Web content from an origin server to a cache server that is close to a user. This means an origin server needs to exist that contains a master copy of the content. If the user has an existing Web site, the existing Web site will be the origin site.

In one embodiment, the present network is comprised of clusters of servers at points of presence located on many different backbone networks around the world. The servers provide global traffic management and distribution services for content of many kinds, including support for HTTP, HTTPS, FTP, and multiple varieties of streaming media.

In a specific embodiment, the present network includes one or more services. Here, the network may offer services, including:

-   1. Global Traffic Management—Provides global load balancing across     multiple origin sites, along with intelligent failover and other     advanced capabilities such as persistence and static mapping. -   2. Content Delivery Network (CDN)—Supports content distribution and     delivery for HTTP, HTTPS and FTP. -   3. Streaming—Supports distribution and delivery of streaming media     in many formats, such as Real Media, Windows Media, QuickTime and     others.

The present CDN service has some advantages. For example, the CDN service helps increase the performance of any conventional Web site or other Internet services. It also helps reduce latency problems and packet loss, and it provides for content synchronization and replication. The network also reduces latency problems and packet loss. Latency problems result when the user's request travels beyond a certain distance or makes a number of network hops. When users request content from the Web or FTP sites, the requests are routed through the Internet to the server. If, as is true for many companies, the servers are located at only one site or a small number of sites, they will not be close to most of the users. Therefore, the users' request for content might traverse many networks to communicate with the desired servers.

Latency problems are often aggravated by packet loss. Packet loss, common on the Internet, tends to worsen at “peering points,” locations where different networks connect. One way to reduce packet loss and latency is to install content servers closer to users and ensure that when a user requests data, the request is routed to the closest available server. The present network has deployed Web caches, streaming, and FTP servers throughout the Internet, on many networks close to end users. In addition, the network uses a Global Traffic Manager that routes traffic to the closest, most available and least loaded server.

The network often synchronizes the content on the customer's origin site with the Web cache servers on the network. When new content is placed on an origin site and when users make requests for that content, it is automatically replicated to Web cache servers in the network. When new content is published on the origin site with a new name, it is generally immediately available from all caches in the present network. For example, the network user might add an object to the site where a similar object exists:

Add “www.customer.com/images/picture2.jpg” to the same site as “www.customer.com/images/picture.jpg.”

When a request for “picture2.jpg” arrives at a cache the first time, the cache in the network determines that it does not have a copy of “picture2.jpg, and the cache will request a copy from the origin site. To keep in synchronization with the origin site, the caches periodically check the content they have cached against the copy of the content in the origin site. For Web content, this is accomplished by periodically performing an “If-modified-since” request back to the origin site to see if the content has changed. This causes content changed on the origin site to be refreshed on the caches at a predefined interval. This interval can be configured depending upon ones needs.

The periodic checking is a common feature of caches but if a piece of content is updated, the old content may be invalidated and the new content published to all the caches in the network. The present CDN service makes this purging possible with a cache control utility that allows you to invalidate a single object, a content directory, or an entire site contained in the caches. In a specific embodiment, cache control is available as part of the service—a service provided to all customers. The present service method provides a comprehensive set of monitoring and administration capabilities for management of the Web site.

In a specific embodiment, the present service method runs on a secure server on the Internet and can be accessed only through a Web browser that supports secure connections (SSL). A username and password are often assigned to a user or customer when signed up for the service.

One of ordinary skill in the art would recognize many other variations, modifications, and alternatives. The above example is merely an illustration, which should not unduly limit the scope of the claims herein. It is also understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit and purview of this application and scope of the appended claims.

2. Procedures

We now describe the procedures that can perform to set up the present CDN service and to monitor the performance of the Web site:

-   A. Implementing the CDN; -   B. Invalidating content by controlling cache; -   C. Monitoring activity; and -   D. Performing tests.     Details of each of these procedures are provided below.

A. Implementing the CDN

To implement the CDN, the customer only need to make minor changes to the Web pages in order to direct user requests to the present Web caches instead of to the origin site. In a specific embodiment, the method is as simple as changing the pointers in the HTML. When a cache gets a request for content, it will return the requested object if it exists in the cache. If the content does not exist, it will retrieve the content from the origin site and return it to the user, as well as cache the content so that subsequent requests for that object are instantly available.

To modify the site, the customer can either: (1) changing the URL; or (2) set up virtual hosting. In a specific embodiment, the site can be modified for redirecting a user requests by changing the URL in the HTML. The following example, a request for a picture, shows the original html and the revised html.

Original Homepage

The original homepage contains the following URL:

-   http://www.customer.com/page.html     The URL contains the following HTML: -   <html><body>     Here is a picture: -   <img src=“images/picture.jpg”> -   </body></html>

Revised Homepage

The “img src” tag has been revised:

-   <html><body>     Here is a picture:

<img   src=”http://customer.speedera.net/www.customer.com/   images/picture.jpg”> </body></html>

With the original configuration, a user's browser requests the picture from the customer.com Web servers:

page.html from www.customer.com

images/picture.jpg from www.customer.com

With the revised configuration, a user's browser requests the picture from the customer.speedera.net Web servers:

page.html from www.customer.com

www.customer.com/images/picture.jpg from customer.speedera.net

Note: If the cache does not hold the requested object in memory or on disk, it makes a request to the origin site and caches it.

In an alternative embodiment, the method can set up virtual hosting so that the user's request for content is directed to the present CDN instead of to the origin site. Here, the customer can change the DNS setup to cause the domain name to resolve to the present network cache servers instead of to the original Web server. The domain name may be changed, for example, change the domain name from www.customer.com to www.customer.com. The present caches in the network can be configured in a way such that when they get a request for www.customer.com content they have not cached, they can make a request to the www.customer.com origin site to get the content. Here, the URLs in the Web pages may not need to be changed.

B. Invalidating Content by Controlling Cache

To invalidate the content contained in the caches, do the following:

-   1. Access the user interface at: -   https://speedeye.speedera.com -   2. Find the Cache Control page (see FIG. 5A) in the Content Delivery     section of the interface. -   3. Enter the URL in the text field. -   4. Click Submit.     For example, if an image: -   www.customer.com/images/picture.jpg

and the user changed the image without changing the name and the user wanted the change to be immediately reflected in all caches in the network, the user could use the present service to invalidate the old content, as follows:

Enter “http://www.customer.com/images/picture.jpg” to invalidate the individual picture, or “http://www.customer.com/images/” to invalidate all content in the images directory, or “http://www.customer.com” to invalidate all content in the domain.

Note: Invalidating any of the above causes the change to “picture.jpg” to immediately be reflected in all the caches.

C. Monitoring Activity

In a specific embodiment, the present method allows the user to monitor the operation of the Content Delivery Network service. The present method shows how much content is being delivered and where it is being delivered. The start section of the user interface contains a table that shows the present domains and associated origin domains your account is set up to use, as shown in FIG. 5B.

In a specific embodiment, the method includes monitoring recent activity, as shown in FIG. 5C. Here, the user can view the current and last 24 hours of content delivery traffic for a given domain:

-   1) Access the user interface at: -   https://speedeye.speedera.com -   2) Find the Recent Activity page in the Content Delivery section of     the interface.

FIGS. 5C-D show several graphs. FIG. 5C shows the amount of traffic served by the content delivery network for that domain over the last 24 hours. The current traffic is shown on the far right. A dotted vertical line separates data from yesterday on the left and data from today on the right. FIG. 5D shows the number of hits per second over the last 24 hours. The total number of hits over the last 24-hour period is shown in the title bar of the graph.

In an alternative embodiment, the method includes monitoring activity by location Here, the user views the last 24 hours of content delivery traffic by location for a given domain:

-   1. Access the user interface at: -   https://speedeye.speedera.com -   2. Find the By Location page in the Content Delivery section of the     user interface.

A world map appears (see FIG. 5E) that shows all the locations that served traffic for the domain.

Below the world map is a bar graph (see FIG. 5F) that shows the amount of traffic served from each individual location over the last 24 hours for a given domain name. This graph is useful for many purposes, such as for determining the optimal location for a second origin site—typically, at the location serving the most traffic, where there is not currently an origin site and when that location is on a different network than the existing origin site.

D. Performing Tests

According to the present invention, selected tests can be performed to check performance, as follows:

-   1) Access the user interface at: -   https://speedeye.speedera.com -   2) Locate the Tests section. -   3) Select the test you want to perform.

A “page check” test can be performed. This test allows the user to check the performance of a Web page from multiple locations. To use the page check program, do the following:

-   1) In the text field, enter the URL to test. -   2) Select the locations from which the user wants to check the page. -   3) Click Check.

At that point, servers at the location(s) selected will be contacted to hit the Web page associated with the URL entered and time how long it takes to download the page and all its components. When the servers have completed downloading the page, the results are shown in the form of tables and graphs. FIG. 5G is the overall performance table. It appears at the top of the results.

In this example, the page took an average of 500 milliseconds (half a second) to download from the first three locations (rows) and 1317 milliseconds (1.3 seconds) from the last location. A server name, physical location, and network location identify each location. For example, the last location in FIG. 5G is labeled as “server-4/sterling/exodus.” This label identifies a server on the Exodus network located in Sterling, Va., USA.

After the overall timetable, details for each location are presented in individual tables. FIG. 5H shows a table containing the details for the location “server-14, dc, cw, a server located on the Cable & Wireless Network in Washington D.C., USA. The IP address of the actual server is shown in the heading of the table so you can perform additional tests, if needed, (traceroute and so on) on the actual server performing the test.

The Location table in FIG. 5H shows data for the www.speedera.com Web site. The graph shows the performance for downloading specific components of the page. This table shows that the majority of the time spent in the download was spent downloading the home page itself. The remainder of the content (all the gifs on the subsequent lines) has been cached and is delivered from the closest and least loaded available server within the CDN, in a fraction of the time. These cached items have a domain name of www.speedera.net.

In a specific embodiment, the colors in the graph show the different components of the download including the DNS lookup time, connect time, and so on. The first time a page is checked, the DNS times will likely be very high. This high reading results from the way DNS works in the Internet. If a domain name is not accessed within a specific amount of time (the timeout period), the information will expire out of the DNS caches. The first request will again need to walk through the Internet's hierarchical system of DNS servers to determine which one is authoritative for a given domain name.

To get even more accurate results, a page can be hit twice, where the results from the second hit are used. This will give a more accurate representation of what the performance is like when the page is being hit on a regular basis. The graph is followed by the actual raw data that makes up the graph. Each row displays the following elements:

-   URL. The URL component downloaded -   IP Address. The IP address of the server contacted to get the data -   ERR. The error code (where 0 is no error) -   HRC. The HTTP response code (where 200 is OK) -   LEN. The length of the data downloaded -   CHK. A checksum of the data -   STT. The timing in milliseconds for the start time -   DRT. DNS response time in milliseconds -   COT. Connection Time—Syn/SynAck/Ack Time -   DST. Data start time when first packet is downloaded -   FNT. Final time when download is complete -   END. The total millisecond timings for portions of the connection

Global Traffic Manager

The present invention provides a global traffic manager. The global traffic manager is coupled to the content delivery network. The following provides a description of the global traffic manager. The description is merely an illustration, which should not unduly limit the claims herein. One of ordinary skill would recognize many other variations, alternatives, and modifications.

1. Procedures

To use the Global Traffic Management service, the following will be used:

A. Domain Name Representing a Service.

The domain name can be delegated for which the users are authoritative so that the present servers are contacted to resolve the domain name to an IP address, or addresses. Alternatively, a domain name can be created for the customer. That name will end with speedera.net, such as customer.speedera.net.

B. More that One IP Address Associated with that Service.

Obtaining more that one IP address for a given service provides the following benefits from the Global Traffic Management service:

Provides better service for clusters of servers on multiple networks. If a location within a cluster fails, or the network associated with that location fails, the system can route traffic to another available network because there is more than one IP address. The system also provides better performance by sending user requests to the closest cluster of servers. These routing options are not available if a local load balancer is used to manage the cluster, since a local load balancer requires that each cluster of servers use a single IP address.

Provides better service for clusters of servers on a single network. If each computer has a different IP address, the Global Traffic Management service can be used to load-balance between individual computers.

Reduces latency for a single cluster of servers that is attached to multiple network feeds. In this configuration, the Global Traffic Management can route around network failures by testing each of the network connections and by routing user requests to the closest working connection.

In a specific embodiment, the present network is comprised of clusters of servers at points of presence located on many different backbone networks around the world. The servers provide global traffic management and distribution services for content of many kinds, including support for HTTP, HTTPS, FTP, and multiple varieties of streaming media. As previously noted, the services include: Global Traffic Management—Provides global load balancing across multiple origin sites, along with intelligent failover and other advanced capabilities such as persistence and static mapping; Content Delivery Network (CDN)—Supports content distribution and delivery for HTTP, HTTPS and FTP; and Streaming—Supports distribution and delivery of streaming media in many formats, such as Real Media, Windows Media, QuickTime and others.

The present Global Traffic Management service routes user requests to the closest available and least-loaded server. The service also tests the servers it manages for service performance and availability, using actual application-level sessions. When a service test fails, the system reroutes the traffic to other available servers. The Global Traffic Management service is based on Domain Name Service (DNS). The Internet uses the DNS to allow users to identify a service with which they want to connect. For example, www.speedera.com identifies the Web service (www) from speedera.com.

When users request a service on the Internet, they request it by its DNS name. DNS names were created to make it easier for users to identify computers and services on the Internet. However, computers on the Internet do not communicate with each other by their DNS names Therefore, when a user enters a domain name, domain name servers on the Internet are contacted to determine the IP addresses associated with that name.

The Network includes specialized domain name servers that use advanced mechanisms to determine the IP addresses associated with a given domain name and service. These servers work seamlessly with the Internet DNS system. To determine the best IP address, or addresses, to return when a user requests a service on the Internet, the DNS system does the following:

-   1. Uses IP addresses to monitor the performance of a service on     individual computers or clusters of computers -   2. Determines latency and load metrics between users and servers on     the Internet -   3. Performs tests on the Internet to determine the quality of     service a user would receive when connecting to a specific computer     or cluster of computers

Procedures

This section describes the procedures you can perform to implement and then monitor the performance of the Global Traffic Management service. To implement the Global Traffic Management service, the customer or user does the following:

-   1. Sign up for the service. -   2. Contact the server location and provide the following     information: The domain name of the service you want the system to     manage; The IP addresses associated with that service; A description     of the service and how it should be tested for performance and     availability; The interval after which tests should be performed;     What the service check should look for, such as specific information     in a returned Web page. Whether the user would like traffic weighted     so that more traffic is sent to one IP address over another.

In addition to the normal routing around failures to the closest server, the system can also be set up for security purposes. The system can contain hidden IP addresses that are only given out in the case of failure of other IP addresses. The user might want to use this feature to prevent a denial of service attack. If one IP address is attacked and becomes unavailable, another will then appear and traffic will be routed to it. This can make attacking a Web server more difficult since the IP address is not published until the failure occurs.

In a specific embodiment, the method allows the user to monitor the operation of the Global Traffic Management service for domain names. Preferably, the method outputs information on a Web-based, user-interface that runs on a secure server on the Internet that can be accessed only through a Web browser that supports secure connections (SSL). Here, a start section of the user interface contains a table that shows all the domains and associated origin domains your account is set up to use. See FIG. 6A.

In an alternative embodiment, we can also view the last 24 hours of traffic management activity for a given domain:

-   1) Access the user interface at: -   https://speedeye.speedera.com -   2) Find the Recent Activity page in the Traffic Management section     of the interface.

The main graph in the page shows how traffic was routed over the last 24 hours. A dotted vertical line separates yesterday on the left from today on the right. The lines in the graph show how many times each IP address was given out. See the example in FIG. 6B.

In the example, the present Global Traffic Management system made 198120 traffic routing decisions over a 24-hour period. The lower decision line in the graph represents an IP address for “Delhi, India.” The upper decision line represents an IP address for “Santa Clara, Calif.; United States.” The Y axis represents the activity levels. The X axis represents the Santa Clara time: N for noon, P for p.m., and A for a.m.

At 6:00 a.m. in Santa Clara, one line dropped to the bottom of the graph and the other spiked upward. This happened because the system routed around a failure at a data center. When the “Delhi” IP address failed its service test, the Global Traffic Management system routed traffic to the “Santa Clara” IP address.

The example also shows that the “Delhi” IP address is more active at night (Santa Clara time), and the “Santa Clara” IP address is more active in the daytime. The difference in activity results from the changes in time zones. When people in India are active, the traffic manager routes their requests to the closest available server with the best service response time. For users in India, when it is their daylight and their peak time, the best IP address is often the site in Delhi. For users in the U.S., when it is their peak time, the best IP address is the site in Santa Clara.

In still an alternative embodiment, we can view the last 24 hours of traffic management activity by location for a given domain:

-   1. Access the user interface at: -   https://speedeye.speedera.com -   2. Find the By Location page in the Content Delivery section of the     user interface.

Here, a world map and a bar chart appear. They show where the traffic manager routed traffic (geographic and network locations) over the last 24 hours for a given domain name. See the example in FIG. 6C. The bar-chart example shows the number of times each location was chosen to serve traffic over the last 24 hours. In the example, the traffic manager chose the “UUNET/sclara” (Santa Clara, Calif.; United States) location to serve most of the traffic.

In other aspects, the method includes performing tests. Here, the interface also contains a utility that allows the user to check a Web page from multiple locations. If an HTTP service is used, a quick status check can be executed as follows:

-   1) Access the user interface at: -   https://speedeye.speedera.com -   2) In the text entry field, enter the URL for the page you want to     check. -   3) Select the locations from which you want to check the page. -   4) Press the Check button. This causes servers at the location, or     locations, selected to download the Web page associated with the URL     you entered in Step 2.

When the servers have completed downloading the page, the page-performance results are shown in the form of tables and graphs. The first table (see FIG. 6D) is the overall performance table. It appears at the top of the results. In this example, the page took an average of 500 milliseconds (half a second) to download from the first three locations (rows) and 1200 milliseconds (1.2 seconds) from the last location.

A server name, physical location, and network location identify each location. For example, the last location in FIG. 6D is labeled as “server-4/sterling/exodus.” This label identifies a server on the Exodus network located in Sterling, Va., USA.

After the overall timetable, details for each location are presented in individual tables. FIG. 5 shows a table containing the details for the location “server-14, dc, cw, a server located on the Cable & Wireless Network in Washington D.C., USA. The IP address of the actual server is shown in the heading of the table so you can perform additional tests, if needed, (traceroute and so on) on the actual server performing the test. The Location table in FIG. 6E shows data for the www.speedera.com Web site.

The graph in FIG. 6E shows the performance for downloading specific components of the page. This table shows that the majority of the time spent in the download was spent downloading the home page itself.

The colors in the graph show the different components of the download including the DNS lookup time, connect time, and so on. The first time you check a page, the DNS times will likely be very high. This high reading results from the way DNS works in the Internet. If a domain name is not accessed within a specific amount of time (the timeout period), the information will expire from the DNS caches. The first request will again need to walk through the Internet's hierarchical system of DNS servers to determine which one is authoritative for a given domain name.

To get more accurate results, a page can be hit twice and the results from the second hit can be used. This will give you a more accurate representation of what the performance is like when the page is being hit on a regular basis. In the Location Table, the graph is followed by the actual raw data that makes up the graph. Each row displays the following elements:

-   URL. The URL component downloaded -   IP Address. The IP address of the server contacted to get the data -   ERR. The error code (where 0 is no error) -   HRC. The HTTP response code (where 200 is OK) -   LEN. The length of the data downloaded -   CHK. A checksum of the data -   STT. The timing in milliseconds for the start time -   DRT. DNS response time in milliseconds -   COT. Connection Time—Syn/SynAck/Ack Time -   DST. Data start time when first packet is downloaded -   FNT. Final time when download is complete -   END. The total millisecond timings for portions of the connection

In a specific embodiment, the Global Traffic Management (GTM) system automatically routes around failures to services on the IP addresses it manages. Here, the system can also be: Adding or removing a domain name from the system; Adding or removing IP addresses from the system; and Changing the way a service is monitored.

The Speedera DNS server (SPD) is the core component of the Speedera GTM solution and provides load balancing across the servers distributed all over the Internet. The SPD acts as the traffic cop for the entire network. It handles the DNS requests from the clients, resolving hostnames to IP addresses. The SPD makes the decisions about which IP address to return for a given hostname based on the static mapping of hostnames to the servers (configuration file), information it collects about the state of the servers in the network (service probes), information about the network latency from the servers to the client (latency probes), the packet loss information for the POP (packet loss probe), bandwidth usage for the POP (SERVPD) and static latency information (client configuration). This enables the invention to direct clients to the servers that are ideally suited to service the client requests.

If SPD cannot answer the request, it will forward the request to the named server. This allows SPD to handle only the queries that are relevant to the GTM solution. SPD handles the following type of queries:

-   -   A Records     -   PTR Records     -   SOA Records     -   LOC Records     -   NS Records     -   ANY Record

SPD server is designed to work around problems in the network. It can handle a single server or a single POP failure. It can also work around more catastrophic failures such as all latency probes going down. In these extreme cases, the load balancing will not be optimal, but the SPD and the entire Speedera Network will still function.

SPD supports a two-tier architecture that can be used to increase the number of DNS servers in the system to more than the maximum allowed for .com domains. It can also be used to direct the client DNS servers to the closet Speedera DNS servers.

SPD logs the statistics about the IP address it gives out in response to incoming requests. This can be used to monitor the effectiveness of the GTM solution in distributing load across multiple servers.

Referring to FIG. 7, the SPD is highly scalable; it uses hashing tables optimized for block memory allocation to speed up access to all the internal tables. It can easily scale to handle thousand of servers and hostnames in the network. The only limiting factor is the amount of physical memory available on the servers. The figure below shows how SPDs interact with other components.

-   1. SERVPD 704, 708, sends the load information about all the servers     in the POP 707, 711, to all the SPD servers 702, 703, periodically.     This information is also used to update the bandwidth usage for the     POP 707, 711. -   2. SPKT 705, 709, sends the packet loss information to all the SPD     servers 702, 703, periodically. -   3. Client DNS 711 sends a DNS request to SPD server 702.     -   3.1. If the SPD server 702 is not responsible for the zone in         which the client address falls, it forwards the request to one         of the SPD servers 703 responsible for the zone. -   4. SPD 703 uses the cached latency, load and packet loss values to     determine the address to return. SPD 703 collects all the probe     information asynchronously to improve the response time for the DNS     requests.     -   4.1. If it was a forwarded request, SPD server 703 sends the         response back to the SPD server 702 that forwarded the original         request. -   5. SPD 702 sends the response back to the client -   6. SPD 702 sends a Latency request to LATNPD 706, 710. If the probe     method for the client 701 is specified in the client configuration     file, it sends the probe method to be used along with the latency     request. SPD 702 sends latency requests only for the servers     configured for the hostname for which it got the DNS request.     Latency requests are only sent for the servers with dynamic latency     value and if latency is factored into the load balancing algorithm. -   7. LATNPD 706, 710, probes the client 701 to determine the latency     and sends the latency information to all the DNS servers in the same     zone.

Configuration Files

The configuration file contains all the static information about the Speedera Network. It contains the list of POPS and the servers present at each POP. It also contains the list of hostnames serviced by the Speedera Network and maps the hostnames to the servers that can serve the content for that hostname. Most of the parameters needed to configure SPD are contained in the configuration file and can be used to fine-tune the load-balancing algorithm, frequency of probes etc.

In addition to the main configuration file, there is a client configuration file that can be used to specify the static latency from a client to the various servers in the network and to specify the latency probe type for a give client. It can also be used to specify conditions under which a client is probed (Never, always, in case of a server failure).

Service Probes

Service Probe Daemon (SERVPD) periodically probes all the servers in the POP and sends the status information back to all the SPD servers in the Speedera Network. There is one service probe for each type of service that is supported by the GTM. This allows the fine tuning of each service probe to return the load metrics that accurately reflect the load on the server for that service. For example, for HTTP the time taken to retrieve a standard Web page from the Web cache as the load metrics. There is also a generic load probe that measures the CPU and memory utilization of the servers. This probe can be used as the load metrics for the services for which there are no custom service probes. Currently there are custom service probes for HTTP, HTTPS, FTP and streaming servers.

The load information is used by the SPD to make the decision about which server to return. SPD keeps track of how old the load information is, so that if the entire POP goes down, it can detect it by simply looking at the load timestamp. If the load information for a server is stale, or the server is down, the SPD tries not to direct any traffic to that server.

The special service type of NOLOAD has a static load value of 1 and its time stamp is always current. This service type can be used to load balance services for which we do not have a probe and want to assume that they are always up. It can also be used to effectively factor serve load out of the load-balancing algorithm.

Bandwidth Probe

There is no separate bandwidth probe. The SNMP probe in SERVPD is used to measure the bandwidth utilization for the switch. The aggregate bandwidth usage for POP is measured as the sum of the load metrics for all the servers in the POP with the service type of “SWITCH”.

Latency Probes

Latency Probe Daemon (LATNPD) is used to determine the network latency from a POP to the client. Whenever SPD gets a request from a client, it sends a latency request for that client to the latency probes. The latency probes then find the network latency from the POP to that client and return it to all the SPD servers in the same zone. LATNPD uses a number of different probes to determine the latency. Multiple probe types are required since all the clients do no respond to a single probe type. Probe types include PING, DNS PTR, UDP packets to high ports looking for a noport responses as well as any others that may generate a reply without spending much time at the target location. The order in which these probes are used to determine the latency can be configured using the configuration file. The type of probe used to determine the latency for a given client can also be specified in the client configuration file.

SPD sends latency requests only for the servers configured for the hostname for which it got the DNS request. Latency requests are only sent for the servers with dynamic latency value and if latency is factored into the load balancing algorithm.

Both LATNPD and SPD cache the latency information. SPD sends a latency request only to a subset of the latency probes and it sends the request only if the latency information it has is stale. LATNPD does a probe only if the latency information it has is stale, otherwise, it returns the values from its cache. This is done to reduce the amount of traffic generated from the latency probes to the client machines. To further reduce the latency probe traffic, static latency information can be input into SPD. SPD also saves the dynamic latency tables across system shutdowns to reduce the latency traffic at startup.

Packet Loss Probes

The Packet Loss Probe (SPKT) is used to determine the packet loss for a POP. A limited subset of SPKT daemons probe all the POPs in the Speedera Network to determine the packet loss for the POPs and report it back to SPD. Only a limited subset of POPs do the actual probing to reduce the amount of network traffic. The probe interval, number of POPs doing the probing, packet size, and number of packets used to determine the packet loss can be fine tuned using the configuration file.

Persistence

SPD also supports persistence. For persistent hostnames, SPD returns the same IP addresses, for a given client. The SPD server maintains a table containing the IP address given out for a given hostname to a client. This table is created dynamically in response to incoming requests and is synchronized across all the SPD servers responsible for a given zone. If the same client tries to resolve the hostname against a different SPD server in the future, it will get the same result. Also, access and refresh timeouts for the persistent entries can be configured on a per hostname basis.

Zones

To reduce the memory requirements and network traffic, the entire Internet address space is broken up into multiple zones. Each zone is assigned to a group of SPD servers. If an SPD server gets a request from a client that is not in the zone assigned to that SPD server, it forwards the request to the SPD server assigned to that zone. The SPD servers need to keep latency and persistence information only for the clients that fall in the zone assigned to the server. The latency probes only send the client latency information back to the SPD servers responsible for that client. Also the SPD servers only need to synchronize the persistence table with the SPD servers responsible for that zone, not all the SPD servers in the network.

Each SPD server probes all the other SPD servers to determine the latency. When SPD has to forward the DNS request to servers in the other zone, it selects the server with the best (lowest) latency value. This allows the SPD server to dynamically load balance between the SPD servers in the same zone and avoid servers that may be down or are having some other problems.

In the DNS response SPD includes the SPD servers that are authoritative for a given client address. That way the client can query the authoritative name servers directly next time, avoiding the delay involved in forwarding the DNS request from one SPD server to another.

Two Tier Architecture

SPD supports a two-tier architecture that can be used to increase the number of DNS servers in the system to more than the maximum allowed for .com domains. It can also be used to direct the client DNS servers to the closest Speedera DNS servers and to prevent the client DNS server from flip-flopping between all the DNS servers authoritative for speedera.net domain.

When returning the NS records, the normal load balancing is performed to determine the SPD servers that are best suited to handle the queries for the client and return only those NS records. This helps in directing the client DNS server towards the SPD servers that is best suited to handle the queries for it.

To support the two-tier architecture the hostname entries are dynamically mapped in the configuration file to the second tier domain names (www.speedera.net to www.edge.speedera.net). SPD provides support for any number of second level domains. The “edge” and “persistent” domains are special domains that are used for the dynamic transformation of the host names.

The persistent.speedera.net domain is used to handle all the persistent hostname queries. If the “persistent” domain is not defined then the root domain (speedera.net) is used to handle the persistent queries.

The following algorithm is used to generate the mapped hostnames and validate the hostnames in the configuration file:

-   -   1. Get the domain authoritative for the hostname, using longest         suffix match. Root is authoritative for all the hostnames that         do not have the speedera.net suffix.     -   2. If the hostname is of the type GTM and persistent         -   a. If persistent domain is defined and the authoritative             domain for the hostname is not persistent.speedera.net then             flag an error         -   b. If persistent domain is not defined and the authoritative             domain for the hostname is not root then flag an error     -   3. If the hostname is of the type GTM do not do the mapping     -   4. If the hostname is persistent and a domain other than the         root is authoritative for that hostname and if persistent domain         is defined and the authoritative domain for the hostname is not         persistent.speedera.net then flag an error     -   5. If the hostname is persistent and a domain other than the         root is authoritative for that hostname and if persistent domain         is not defined flag an error     -   6. If a domain other than the root is authoritative for the         hostname do not do the mapping     -   7. If the hostname is persistent and “persistent” domain is not         defined, do not do the mapping.     -   8. If the hostname is not persistent and “edge” domain is not         defined, do not do the mapping.     -   9. If the hostname is static do not do the mapping.     -   10. If the hostname is persistent, MapDomain is         persistent.speedera.net.     -   11. If the hostname is not persistent MapDomain is         edge.speedera.net.     -   12. If the hostname belongs to one group of servers and uses         global load balancing parameters, map the hostname to         <service>-<group>.<MapDomain>     -   13. Remove the domain suffix from the hostname     -   14. Map the hostname to <prefix>.MapDomain>

The Speedera Network consists of a number of Linux machines running Speedera software. Speedera software consists of eight components that are delivered as a single product. When deployed across a large number of machines, it creates a network that provides a complete solution for content hosting and delivery.

Customers can store content such as HTML, images, video, sound and software in the network for fast and highly available access by clients. The network also provides load balancing and high availability for servers outside the network. Customers with generated content, such as search engines, auctions and shopping carts, can use the latter feature to add their own content servers to the network.

The system requires no software or hardware to be installed or run at a customer site. The system may be monitored using a standard Web browser. It provides an HTML interface that displays the networks current status as well as historical statistics.

Software Components

The system is comprised of the following distinct software components:

-   NameServer -   WebCache -   Streaming Media Servers -   FileSync -   NetProbes -   LogServer -   NetView -   AdminTools -   Shared

NameServer

DNS server software that performs name to IP address mapping. When queried to resolve a name from a client's DNS server, it returns an IP address that has the ability to serve content for that name and that is best suited to handle the request in terms of load (service health), latency, packet loss and availability. The DNS server writes log information to files that are picked up and maintained by the LogServer software.

WebCache

Caching Web server software that responds to requests for Web content from clients (Web browsers). If the requested content does not exist in memory, it will generate a request to an origin site Web server to fetch the content. The caching servers write information about the content delivered to log files that are picked up and maintained by the LogServer software.

Streaming Media Servers

The streaming media in the servers will be off the shelf streaming media servers including ones from Real Networks, Microsoft and Apple. A logging system allows the logs to be picked up by the LogServer software and plugins allow the configuration of the servers remotely.

FileSync

The FileSync software is the infrastructure to support publishing files and synchronizing them from one location to many locations. These are used to publish large download files and also to publish on-demand streaming media files to the streaming media servers.

NetProbes

A number of probes that include probes that:

-   Determine server load and availability (including service health,     load and availability) -   Determine packet loss and latency problems on links in the network -   Perform content checks to ensure servers are delivering correct     content -   Determine latency between points on the network and clients of the     network -   Perform ongoing monitoring of services

Probes run constantly and send results to servers running NameServer software. The also log results to a log file that is picked up and maintained by the LogServer software.

LogServer

Server software that picks up log files and then transmits them, receives them in a central location, stores them on disk, breaks them out into categories and processes them to generate statistics and monitoring information. The software also responds to requests for current and historical information from servers running NetView software.

NetView

Server software that provides an HTML interface to current and historical statistics for end-customers and network operations. Information about the network is obtained from servers running LogServer software. Web server CGI programs are used to provide the HTML user-interface. NetView software also provides an interface that allows customers to flush content from the network as they update the content on their servers, manage files in the network, and set up live streaming events.

AdminTools

Tools to configure and administer the site including tools to spider a Web site to load the caches with content and tools to update the global configuration file.

Shared

A set of client and server programs that all the various software components require. This includes a server that transmits and receives configuration files. Installing this software is not an option. It is installed automatically when any one of the other software components is installed.

Any combination of the software components (with the exception of “Shared” which is always installed) can be installed on a single machine. In a normal deployment, however, many machines will serve a single purpose (DNS name server, for instance) and will only have one of the software components installed.

How the System Operates

The Speedera Network consists of a number of server machines installed at various points of presence (POPs) around the world. Each POP will contain some mix of the Speedera software.

The vast majority of POPs will contain NetProbes and WebCache software. The NetProbes software performs network latency probes from each POP to determine the latency from users to the POP. The NetProbes software will also run probes against other POPs and perform content verification to ensure machines at the various POPs are operating correct. The WebCache software is used to deliver content.

A number of the POPs will need to be outfitted with large disk storage and will contain Streaming Media servers and FileSync software. A limited number of POPs will contain NameServer software to perform traffic management for the whole system.

The Speedera Network Operations Center (NOC) contains NetView, AdminTools and LogServer software. Two NOCs can be created for redundancy and in the case of the failure of one, the backup NOC should pick up automatically.

With respect to FIG. 8, a four POP Speedera Network is shown. The dashed lines and triangles in the diagram show the path network traffic follows when a piece of stored content is initially published to the network. Three content delivery POPs 802, 803, 806, and one NOC 805 are shown. Two POPs are hosted at Globix, one in Europe 802 and one on the east coast of the USA 803. One POP is deployed at Exodus on the west coast of the USA 806.

As stated above, the POP servers contain a mix of Speedera software. POP 802 contains NetProbes 807, WebCache 808, 809, and WebServer 810. POP 803 contains NetProbes 811, WebCache 812, 813, WebServer 814, and NameServer 815. The NOC 805 contains NetView 819, AdminTools 818, LogServer 817, 816.

Customers of the Speedera Network will maintain their own Web server (or servers) with their copy of their content on it. They don't have to change the way they test and manage their Web site in any way to use the content hosting service.

The Speedera network provides two primary services. First, it provides content hosting for content that can be cached and stored (images, video, software, etc.). Second, it provides load balancing and traffic management for services that can't be stored. The latter is used to load balance search engines, shopping engines, etc. The network also contains other services including monitoring and live streaming, however, the most basic services are content hosting and load balancing.

Content Hosting

To host HTTP or HTTPS Web content on the Speedera network, customers either delegate a DNS name to Speedera or host content under a speedera.net domain name.

In the former case, the customer might delegate “images.customer.com” to Speedera's DNS servers using a CNAME or by directly delegating the domain. If the customer already uses an images.customers.com domain (some customers use this method for static content, for example EBay uses pics.ebay.com) they wouldn't need to make any changes to their Web site to have their content published to the network. The Speedera network gets all hits to images.customer.com and any time the Speedera network gets a hit for content it did not contain, it goes back to the customer's Web site to retrieve the content and store it in the system. Once stored in the system, the customers Web site is never hit for that piece of content again.

When a customer updates its Web site, it can tell the Speedera network that the content was updated by entering its URL on a Web page used by Speedera customers to invalidate content. If multiple changes to their Web site are made, they can invalidate whole trees of content or simply the whole Web site. In the latter case, their Web site would be flushed from the system and the next hit would cause the content to be grabbed from their Web site.

Alternatively, the Web cache could make if-modified-since requests back to the origin site at specified intervals to check to see if the content it has cached is fresh. Also, the cache can look at expiry headers in the HTTP content it retrieves from the origin site to ensure freshness.

If the customer uses the speedera.net domain name to host their content, they don't need to delegate a domain name to Speedera. Speedera will create a “customer.speedera.net” domain name and associate it with some portion of the customer's Web site. If customer.speedera.net gets a hit for content it does not contain, it will hit the appropriate content on the customer's Web site to pick up that content and store it in the network.

In both cases, the path network traffic flows is similar. Consider the case where the customer has delegated images.customer.com to Speedera to host their images. The path of the first user request is as follows:

-   1. User hits www.customer.com generating a DNS request to their     client DNS -   2. Request to resolve www.customer.com from client DNS goes to     customer.com DNS server -   3. customer.com DNS resolves the name to the customer's Web server     IP address -   4. Web page is returned to user -   5. Web page has embedded tags to get images from     images.customers.com -   6. Request to resolve images.customers.com goes to a Speedera DNS     server -   7. NameServer software on the DNS server returns the Speedera     WebCache IP address that is closest to the user, available and least     loaded -   8. WebCache does not have the content for the request so it performs     HTTP request to the customer's Web site to obtain the content

The next time the request for the same content comes through the system, it will come directly from the cache.

If a customer hosts content off the speedera.net domain name (customer.speedera.net), the process is exactly the same as the process when the content is hosted on a name delegated by the customer.

Traffic Management

Another service the Speedera network provides is load balancing and traffic management for servers that aren't in the network. By combining traffic management and content hosting, the network can provide a complete load balancing and high availability solution for Web sites.

The network provides load balancing at the DNS level. As in content hosting, the customer will either delegate a DNS name to Speedera or be assigned a speedera.net domain name. When the Speedera DNS server receives a request to map a name to IP address it will return an IP address that is best suited to handle the response. The IP address returned will be the server that is closest to the user (latency), has the least load, and that is available and can handle hits to that domain name.

The DNS level load balancing will commonly be used in combination with content hosting. When both are used in combination, the path a user request follows is:

-   1. User hits www.customer.com generating a DNS request to Speedera     DNS -   2. Speedera DNS determines which customer Web server is best suited     to handle request -   3. Customer's Web server generates main page and returns to user -   4. Web page has embedded tags to get images from     images.customers.com -   5. Request to resolve images.customers.com goes to a Speedera DNS     server -   6. NameServer software on the DNS server returns the Speedera     WebCache IP address that is closest to the user, available and least     loaded -   7. If WebCache has content cached the content is returned, otherwise     process is as above

Notice that high availability and high performance are available from the beginning. All DNS requests go through the Speedera network. Content that can be hosted is hosted through the Speedera network so it may be delivered from a point closest to the user.

To determine latency from the client DNS to the customer's server IP addresses, latency information is used from the closest POP to the customer location. In some cases, the customer may be hosting at a co-location facility we already have latency probes running on. For large customers that have servers located at a location that is not close to one of our POPs, we could run a latency probe server at their site.

When used for traffic management, the customer must have a setup that allows for failover. If the customer only has one IP address for their Web site, then the Speedera network can't provide any load balancing or high availability for it. When the customer has 2 or more IP addresses, the network can provide load balancing, high availability and closest point matching for their service.

Configuration

The configuration of the Speedera Network is maintained by centrally managed configuration files. These files are known as the “global configuration” files or “Speedera configuration” files. Every server in the network that needs configuration information has a copy of the appropriate current Speedera configuration file.

A configuration file contains all the configuration information for that portion of the network. Some of the data the configuration file contains is:

-   List of servers allowed to change the configuration -   List of domains the network is responsible for -   List of services the machines in each POP supports -   List of probes that perform latency checks at each POP

At any time, a new configuration file can be pushed to all machines that need it in a safe manner using the AdminTools software.

No statistics, status or extended information is kept in the configuration file. It must contain only the configuration information and not customer names or any other information not required by the network to keep its size at a minimum and to reduce the frequency of it needing updates.

Monitoring

Real-time and historical information about the site is available through HTML by connecting to a server running NetView software.

Maintenance

The system is maintained using the AdminTools software. Some limited maintenance is available through HTML including the ability to purge content from all the caches in the network when original content is updated.

Software Requirements

Referring to FIG. 9, the Speedera software consists of several distinct software components. The various components, NameServer server 901, NetProbes 907, LogServer server 903, NetView server 902, WebCache server 906, and WebServer server 905, interact with each other and the customer Web site 904, as described above.

WebCache Description Terminology

-   CacheServer (aka WebCache) -   A POP Server that Serves Requests that are Cached in Memory and on     Disk.

WebCache is the Web caching server software that responds to requests for Web content from clients (Web browsers). If the requested content does not exist in memory or on disk, it generates a request to an origin site to obtain the content. The caching servers write information about the content delivered to log files that are picked up and maintained by the LogServer software.

At a regular fixed interval, the server compresses and sends the logs of the content delivered to the log analysis servers. This information is used for billing as well as by customers for log analysis. In the case where a hardware box is used, the server that sends the logs will need to be written as a separate daemon, but it will exist as part of the WebCache software.

Netprobes Description

The NetProbes software component comprises server software executing on a computer system that performs probes to:

-   Determine server load and availability -   Perform content checks to ensure servers are delivering correct     content -   Determine packet loss and latency on individual routes -   Determine latency between points on the network and clients of the     network -   Perform ongoing monitoring of services

Probes run constantly and send results to servers running NameServer software. They also log results to a log file that is picked up and maintained by the LogServer software.

The NetProbes software performs service availability/metric and latency probes and sends the results to servers running NameServer software. There are 2 fundamental probes: (1) service probes; and (2) latency probes.

Service probes determine service availability and load (metrics) for each content delivery machine in the network. Service probes monitor things like HTTP total response time, FTP total response time, etc. Service probes run constantly, sending current metric and availability information to all DNS servers in the network. Probe intervals and configuration of service probes are set in the global configuration file.

Latency probes determine latency from their point to client DNS servers that send requests to Speedera DNS servers. The Speedera DNS servers drive the latency probes. When a DNS server determines that it needs latency information from a probe, it sends a request to the probe and the latency probe will probe the client DNS server and respond with the result.

The probe servers do not store the results of the probes, they simply send them to other servers over the network. Each piece of probe information has a timestamp of when the probe occurred so the receiving server can determine how stale the probe information is.

Overview

The NetProbes servers are responsible for providing the network with service and latency metrics. The NetProbes servers continuously perform probes and send metrics to DnsServers and LogServers.

With respect to FIG. 10, there are two different types of NetProbes, a ServiceProbe 1003 and a LatencyProbe 1001. In the Speedera configuration file, each POP is assigned an IP address for a ServiceProbe 1003 and LatencyProbe 1001. They may be different but in most cases, a single machine will perform both service and latency probes.

ServiceProbes

A ServiceProbe 1003 figures out service metric information for servers in the Speedera Network. Each server in the Speedera Network supports one or more services. For example, a Web server machine provides an HTTP service. An FTP server provides an FTP service.

The value of a service metric is dependent on the metric type. For example, an HTTP metric may have a value that represents the machine's response time to an HTTP request in milliseconds.

The CPU/memory load of a machine is available using the LOADP service if the machine is running a LOADP daemon. LOADP is a Speedera protocol described later in this document that returns a value describing a combination of CPU load and swap memory utilization.

In the Speedera configuration file, each DNS name has a set of services associated with it. The ftp.speedera.com DNS name may serve FTP content and therefore have an FTP service associated with it. A www.speedera.com domain name would have the HTTP service associated with it. A speedera.com domain name may have FTP and HTTP services associated with it.

Service metrics are used by DnsServers 1008 to determine the best server to return for a given DNS name. A DnsServer 1008 getting a request for ftp.speedera.com, for example, would know the request is for the FTP service and could compare the FTP service metrics of two servers to determine which is the best to return.

A DnsServer 1008 getting a request for speedera.com may not know which service will be utilized, so it may simply use the LOADP metric to determine which machine has the least loaded CPU and available memory.

LatencyProbes

A LatencyProbe 1001 figures out the latency from its location to other locations on the Internet. DnsServers 1008 need to know the latency from various latency points to determine which point is closest to a user.

When a user hits a Web site, such as www.speedera.com, his machine makes a request to its local DnsClient. This DnsClient, in turn, ends up making a request to a Speedera DnsServer 1008 if the server is authoritative for the www.speedera.com name.

When the Speedera DnsServer 1008 gets a request from a DnsClient, it needs to determine which servers are closest to the client as well as which servers have the best metrics to handle the request.

To determine which servers are closest to the client, the DnsServer 1008 will consult tables that contain latency information from various LatencyProbes. Each server in the Speedera Network is contained in a POP and each POP has a LatencyProbe 1001 assigned to it.

It's the job of the LatencyProbes to perform latency tests to DnsClients. A LatencyProbe 1001 builds up a table of DnsClients to test over time, receiving the list of which DnsClient IP addresses to probe from the DnsServers in the network.

ServiceProbes

ServiceProbes determine service metric information for servers in the Speedera Network. The following types of service probes are available:

-   HTTP -   HTTPS -   FTP -   Streaming Media (Real, Microsoft, etc.) -   Generic SNMP

Configuration

A ServiceProbe determines which metrics to calculate and what servers to probe by reading the Speedera configuration file. The configuration file contains a LatencyProbe and ServiceProbe entry for each POP.

When the ServiceProbe is configured, it will scan the entire list of POPs in its configuration and examine each ServiceProbe entry to determine if it is the ServiceProbe for that POP. If it is, it will read the list of servers and services contained in the POP and add them to the list of servers to monitor.

Tests

Each service supported by the Speedera Network has a metric test associated with it. HTTP, for example, will have a metric associated with it that is the total time it takes to process a HTTP request. The service test for HTTPS is identical to the service type for HTTP. The only difference being that a secure session is established for the GET request. Secure sessions are not shared; rather a separate secure session with full key exchange is done for each test. For FTP, the test consists of establishing a connection to the FTP port on the server, and making sure that a ready response (220) is obtained from the FTP service. The connection is then closed. Different types of search engines will have different types of tests.

At first glance, it may seem that we could simply use the LOADP metric as the HTTP or FTP metric. However, the LOADP metric doesn't accurately reflect how long a given HTTP request might take to execute on a server. It's best to produce a metric that is based on user-experience rather than trying to infer a metric from other means.

The ServiceProbe performs metric tests at various intervals and adds a line for each test to an internal table. The internal table looks like:

TABLE 1 Server Metric Table Example ServerIP ServiceID ErrorCode Metric TimeStamp 1.2.3.4 [1] HTTP [0] NONE 80 103019419 1.2.3.4 [0] LOADP [0] NONE 340 103019421 1.2.3.4 [2] FTP [5] 65535 103019422 BAD_REQUEST 2.3.4.5 [1] HTTP [0] NONE 70 103019424 2.3.4.5 [0] LOADP [0] NONE 330 103019425

The ServiceID field in the table is the id that identifies the service the metric is for. Each service in the Speedera network has an id specified in the services section of the Speedera configuration file. The ErrorCode field is an internal service-specific error code that can be used to help trace failures. An ErrorCode of 0 is used to signify no error. A metric value of 65535 also generally denotes a verification or timeout failure. The TimeStamp is the time the metric test was performed.

A test can fail either from a verification failure or a timeout. An example of a verification failure might be an HTTP test failing because a response does not contain an expected piece of text. Each test can also time out if there is no response for some period of time. The timeout, in milliseconds, for each test is set in the Speedera configuration file.

SERVP Protocol

At various intervals, the ServiceProbe sends an update to all DnsServers in the Speedera Network using the Speedera SERVP protocol and writes the update to a log file. The update consists of the values of all tests since the last update. The Speedera configuration file contains two values that determine the interval for server metric updates “send interval” and “send size”.

The send size is the maximum size of an individual server metric update in bytes. As the probe runs, it accumulates metrics and keeps track of the size of the update packet related to the metrics. If the update packet reaches the size of the send size, the probe sends an update. If the send size is not reached, then the packet is sent when the send interval expires. This causes the update to be sent when it gets too large, by reaching the send size, or when the send interval expires.

Each update is formatted according to the SERVP protocol. All integer values passed in the protocol are passed in network byte order.

The protocol is defined as:

TABLE 2 SERVP Server Metric Update Protocol Name Type Description magic uint32 magic number numRows uint16 number of rows of data IPAddr uint32 row[0] IP address serviceID uint16 row[0] service ID errorCode uint16 row[0] error code metric uint16 row[0] metric timeStamp uint32 row[0] time stamp . . . . . . . . . timeStamp uint32 row[n] time stamp

LOADP Protocol

To determine the load on a machine, the invention provides a LOADP server. The serviceProbe sends a request and a LOADP server responds with a packet containing the various metrics of the server, e.g. Cpu, memory, snmp, network and scsi metrics. The service probe combines the server metrics to arrive at a load metric which is then sent to the server.

The communication between the client and server is accomplished using the LOADP protocol. All integer values passed in the protocol are passed in network byte order.

A request to a LOADP server follows the following protocol:

TABLE 3 LOADP Request Name Type Description magic uint32 magic number

A response from a LOADP server follows the following protocol:

TABLE 4 LOADP Response Name Type Description magic uint32 magic number Error uint32 Error code - bit mask; various bits are set to indicate different errors: #define LOADP_OK 0x0 #define LOADP_ERR_LOAD 0x1 #define LOADP_ERR_MEMINFO 0x2 #define LOADP_ERR_NETINFO 0x4 #define LOADP_ERR_SNMPINFO 0x8 #define LOADP_ERR_SCSIINFO 0x10 Time Uint32 Timestamp when load was measured. The LOADP server refreshes its metrics at the most once every 10 seconds. CPU/MEM Info LoadAverage uint32 Avg load in the last minute MemTotal uint32 Memory avl on machine (bytes) memUsed uint32 Mem used on machine (bytes) swapTotal uint32 Total swap space (bytes) swapUsed uint32 Used swap space (bytes) Network Info inBytes uint32 Incoming bytes inPkts uint32 Incoming packets inNetErrs uint32 Network errors on incoming packets inDrop uint32 inFifo uint32 Erroneous imcoming packets - dropped, Fifo overflow, fram errors inFrames uint32 outBytes uint32 Outgoing bytes outPkts uint32 Outgoing packets outNetErrs uint32 OutDrop uint32 Errors in outgoing packets—Network errors, dropped packets, Fifo errors outFifo uint32 colls uint32 Collisions carrier uint32 Carrier loss SnmpInfo inRecv uint32 Incoming packet statistics inHdrErr uint32 inAddrErr uint32 inUnknownPro uint32 to inDiscards uint32 inDelivers uint32 outReqs uint32 Ougoing packet statistics OutDiscards uint32 outNoRoutes uint32 reasmTimeout uint32 Reassembly statistics ReasmReqd uint32 ReasmOKs uint32 reasmFails uint32 fragOKs uint32 Fragmentation statistics fragFails uint32 fragCreates uint32 TCPInfo maxConn uint32 TCP stats - some of these stats are not correctly maintained by the current version of Linux maxConn is always reported as 0. activeOpens uint32 passiveOpens uint32 PassiveOpens is always 0. failedAttempts uint32 estabRsts uint32 currEstab uint32 inSegs uint32 outSegs uint32 retransSegs uint32 inTcpErrs uint32 outRsts uint32 UDP Info InDGram uint32 UDP statistics inNoPort uint32 inUdpErrs uint32 outDGram uint32 SCSI Info numTxn uint32 SCSI stats numKBytes uint32 LoadP Metrics numReq uint32 Number of requests received by LoadP numRefresh uint32 Number of times LoadP refreshed its metrics on the machine errReq uint32 Number of err requests errRespSend uint32 Number of errors in sending responses ErrLoad uint32 errMemInfo uint32 errNetInfo uint32 Error count for various types of load metrics: load, meminfo, net info, snmp info, scsi info errSnmpInfo uint32 errScsiInfo uint32 numSigHups uint32 Number of SIGHUPS received since last started

The load value returned by the service probe to Speedera DNS currently is:

load=(10*loadAverage)+(swapSpaceUsed/1000000)

A machine's loadAverage is typically in the range of 1.0-10.0. The swapSpaceUsed is in bytes and the division by 1M turns the right hand side into megabytes of swap space currently used. If the server can't calculate the load value for some reason, it will return a load of 1000.

Logging

When a SERVP server sends an update, the update is also written to a log file. The format of the log output is the same as the update, except:

-   there is no magic or numRows (no header) -   the log file is in text file format -   there is a delimiter between columns (pipe symbol or similar)

Referring again to FIG. 10, the Speedera LogServer daemons 1004 perform the job of sending the log file to a central location for processing.

LOADP servers perform no logging of requests or responses.

Latency Probes

LatencyProbes figure out the latency from the POP location to the client's location (normally local DNS server). Each POP in the Speedera Network has a LatencyProbe associated with it. Any number of POPs can share the same LatencyProbe.

In the normal case, when a DnsServer gets a request from a DnsClient, it refers to the metric tables it has built up from each LatencyProbe, finds the DnsGroup entry for the DnsClient, and compares latency values to find the best IP address to return. If it can't find an entry in the tables for the DnsClient, it just returns a “best guess” IP address and sends the IP address of the new DnsClient to all NetProbes in the network at the next update interval.

At a regular interval, the DnsServers in the Speedera Network will send a list of the DnsGroups and DnsClient IP addresses that have recently made requests back to the NetProbe servers. This is used by the LatencyProbe to update the list with new DnsGroups and to update the use counter information for existing DnsGroups.

Configuration

A machine determines if it is a LatencyProbe by looking at the LatencyProbe value for each POP in the Speedera configuration file. If it finds its IP address as a value for a LatencyProbe, it becomes an active LatencyProbe.

The Latency Probe also parses the DNS Zone configuration in the Speedera Configuration file, to determine all the DNS servers to latency metrics needed to be sent.

Tests

Each LatencyProbe maintains a table of latency metrics from its location to a list of DnsGroups. A LatencyProbe will scan its table at a regular interval, looking for entries that are stale and perform probes to update the stale values.

The LatencyProbe maintains an internal table, with one row per Dns Group. The columns in the table are as follows:

-   DnsGroup—a group of DnsClient servers (DnsClient IP addresses masked     to 255.255.255.0) -   DnsClient[1, 2, 3]—IP addresses for 3 (or less) DnsClient servers in     the group -   ProbeType Reverse name lookup/traceroute -   clientIndex Index into dnsclient[ ], active client -   ProbeStatus Status of the probe -   TraceRouteInfo All the traceroute related data -   ProbeTimeStamp: time stamp of when the probe is issued -   LatencyValue—the latency from this location to the DnsGroup -   LatencyValueTimeStamp—the LatencyValue time stamp -   prevLru: prev pointer in LRU list of client DNS records -   nextLru: next pointer in LRU list of client DNS records -   nextInHash: pointer to the next element in the same bucket

LatencyProbes perform latency tests by calculating the round trip time for sending a packet to a DnsClient in a given DnsGroup. A latency value from any DnsClient in the group will be considered to be the latency for the whole group.

The probe has a number of tests it can perform to try and determine the round trip time. These include:

-   PING -   UDP Reverse Name lookup (request for the DNS name of the DnsClient     IP address) -   UDP Packets to high ports numbers

LATNPD can be configured to try the different probe types in any order.

Reverse name lookup is a standard DNS query that specifies a client IP address and asks for the client name. When the client responds that gives the round trip time that is used as a latency value. If the reverse name lookup succeeds that latency value is FULL latency measurement. But if the lookup fails LATNPD tries Traceroute.

The UDP packets to high ports is much like traceroute which sends a raw UDP packet with large TTL value (64) to an unreachable port (33434) on the client DNS. This generates an ICMP unreachable port error message to the latency daemon. This response is used as a measure of latency. When the unreachable port error arrives, it suggests that the client is reached, this is considered to be FULL latency measurement.

However, sometimes the trace route message gets lost and no response comes back—so the probe times out. The probe (UDP) is repeated with a TTL value of, four, for example, addressed to the client Dns with the hope that we can reach at least four hops from the source. If this succeeds (LATNP gets a ICMP error message with code TIMEXCEED), repeat this probe process with a TTL value incremented by four, for example, (TTL now is eight) and keep doing this until we get no response. This will indicate the last reachable router and that is used as a proxy for the real client to measure the latency value. This is treated as PARTIAL latency data.

Once FULL latency data is achieved using a client, the probe is sent only to that client even if Speedera DNS sends new clients for the same group.

As mentioned above, LATNPD stores up to three IP addresses for each client DNS group. So if a new client is added to a group that has only PARTIAL latency data available, it designates the new client as the active client and starts the probe process all over, starting with reverse name lookup. This is done so that the new client might give the FULL latency data.

When a new client is added to a client DNS group, LATNPD tries to find a free dnsClient entry for the new client address. If it does not find a free entry it tries to replace a client that got only PARTIAL latency data and is not actively probed.

At an interval controlled by the configuration file, the LatencyProbe sends an update to all DnsServers in the Speedera Network with new DnsGroup latency information. Each DnsServer maintains a latency table associated with each LatencyProbe.

LATNP Protocol

The LatencyProbe uses the Speedera LATNP protocol to receive requests for latency metrics from the DNS servers and to update the DNS servers with the latency information for DNS groups.

The LATNP protocol implementation is supported using two messages. Both messages share a common header. The header is followed by a variable number of request elements for the Latency Request and by a variable number of latency metric elements for the Latency Metric Message.

The Latency Request Message consists of the header followed by a sequence of IP addresses, representing DNS groups for which a metric is desired. The format is as defined below:

TABLE 5 LATNP Latency Request Message Name Type Description Cookie uint32 magic number Version uint32 Version Status uint32 Status (ignored for requests). NumElem uint32 Number of request elements in the request message Ip address uint32 Row[0] IP address belonging to the DNS group for which metric is needed IP address uint32 row[n] IP address

The Latency Metric Message consists of the common header followed by a variable number of metric elements. Each metric element consists of the DNS group, latency value, and the timestamp at which latency was measured:

TABLE 6 LATNP Latency Metric Message Name Type Description Cookie uint32 magic number Version uint32 Version Status uint32 Status for response messages. Following status codes may be returned: LATNP_STATUS_OK LATNP_STATUS_VERSION_MISMATCH LATNP_STATUS_UNSPEC_ERROR (unspecified error) NumElem uint32 Number of latency metric elements in the message DnsGroup uint32 DnsGroup[0] LatencyValue uint32 Latency Value for the Dns group[0] Latency uint32 Timestamp at which latency for the Dns group was TimeStamp measured[0] DnsGroup uint32 DnsGroup[n] LatencyValue uint32 Latency Value for the Dns group[n] Latency uint32 Timestamp at which latency for the Dns TimeStamp group was measured[n]

In both cases, from the DnsClient to the LatencyProbe and from the Latency Probe to the DnsClient, updates are sent at an interval defined in the Speedera configuration file. Each Latency Metric message contains any new latency measurements made during the interval between the previous message and the present message.

Logging

The Latency Probe logs the Statistics data periodically based on the logInterval set in the Speedera config file.

The statistics are aggregated for all the Speedera DNS servers. The layout of the log file is as described here:

TABLE 7 Log file layout Name Type Description TimeStamp uint32 Timestamp when the log file is wriiten Interval uint32 LogInterval, time interval btw 2 consequtive logs. Reqs uint32 Total # of request packets from all the Speedera DNS servers. Resps uint32 Total # of response packets to all the Speedera DNS servers. InvalidReqs uint32 Total # of inavlid requests from all the DNS servers respErrors uint32 Total # of errors in sending responses (communication errors) reqMetrics uint32 Total # of metrics in all the requests from Speedera DNS servers. RespMetrics uint32 Total # of responses sent in all the responses to Speedera DNS servers. RevNameReqs uint32 Total no. of reverse name probes done RecNameFails uint32 Total no of reverse name probes that failed. TraceRoutes uint32 Total no. of traceroute probes issued TraceRouteFails uint32 Total no. of traceroute probes that failed (no response at all) TraceRouteFulls uint32 Total no. of traceroute probes that reached the client Dns TraceRoutePartials uint32 Total no. of traceroute probes that resulted in partial latency values. ProbeSendErrors uint32 Total no. of errors in sending probes. Hits uint32 Total no. of hits for client IP address MissesNew uint32 Total no. of misses when a new client IP addess is looked up in the client Dns Hash table of Latnpd. This results in allocating a new client dns record and starting a probe. MissesStale uint32 Total no. of times a client IP address is found in the client Dns Hash table but invalid because since it is stale. This results in sending a new probe and waiting for the response. NonStaleReplaced uint32 Total no. of client Dns Records that are not stale but replaced to accommodate new clients.

LogServer Description Terminology POP Server

Any server in a POP that runs a log distributor daemon that sends log files to the log collector daemons on the log servers.

Log Server/Database Server

A server machine that collects log files from the POP servers via the log collector daemons. These log files are then processed and sent to a database server. The database server stores log files generated by log servers as tables. The Netview servers contact the database server to extract statistics like cache hits, billing etc.

Netview Server

A server that runs the user-interface to the Speedera Network via a Web server. The CGI scripts on this server generate requests to the database server on behalf of the clients that are connected to it.

-   For each unique customer hostname, the server must create a separate     log file. -   Log files will be rotated on a regular basis (after a certain     timeout interval or a certain size threshold). Completed log files     will be placed in a well known directory. They will be shipped     automatically by the Log Server daemons. -   Log files will contain the following fields for each serviced     request. These fields will be delimited by a separator such as |or     ̂. This allows easy insertion in to a database on the receiving end.     -   Date     -   Time     -   Full URL     -   Request Status (miss, hit . . . )     -   Request type (?)     -   Number of bytes -   Log files will be named according to the naming convention in the     Log Server Specification. The name of the file identifies the     customer name, the machine name, the machine number, the location,     network etc.

Overview

With respect to FIG. 11, the logging subsystem consists of the following daemons that will be used to distribute log files from the POP servers and collect them on the Log servers. In addition to the daemons, there will be tools to dump log data into a database. The database will then be queried by tools on the Netview servers for statistics and billing information etc.

Log Distributor Daemon

The log distributor daemon (sldd) 1113, 1114, sends log files on a POP server 1111, 1112, to a log collector daemon (slcd) 1107, 1109, running on a Log Server 1105, 1106. Each log distributor daemon 1113, 1114, looks in a well known location for files it needs to send. The sldd 's 1113, 1114, are multi-threaded and can send multiple log files simultaneously.

Log Collector Daemon

The log collector daemon (slcd) 1107, 1109, collects log files from the log distributor daemons (sldd) 1113, 1114, and places them in directories specified by the date on which the files were received. This daemon is also multi-threaded to handle simultaneous connections from multiple log distributor daemons.

Database Insertor Daemon

The database insertor daemon (sldb) 1108, 1110, collects the log files from the directories where the collector daemon(slcd) 1107, 1109, has placed them. It then opens a connection to the database and puts the contents of the log files into tables. The database insertor is multi-threaded and can load multiple log files simultaneously into the database.

Log Distributor Daemon—sldd

A log distributor daemon 1113, 1114, running on a POP server 1111, 1112 does the following:

-   -   1. Check a well known directory(that is configurable) for files         that need to be sent to the log collector daemons. The file name         fully qualifies the type of file it is (one of either NetProbe,         DNS or WebCache).     -   2. Create a new thread for each file that is ready.     -   3. Each thread determines the Log Server IP to send the file to         by querying the DNS server. A query is made to log.speedera.com         If multiple IPs are returned, any random IP will be selected. In         case, the connection to that IP fails, then all other IPs will         be tried in sequence till a connection is established or all         IP's have been tried.     -   4. Compress the log file and send it over.     -   5. Exit the thread.         Log Collector Daemon—slcd

The log collector daemon 1107, 1109, running on the Log Server 1105, 1106, does the following:

-   -   1. Listen for connections from the log distributor daemons         (sldd) 1113, 1114, and create a thread for each connection when         it is established.     -   2. Send a ready message indicating available pre-allocated disk         space for the file to the sldd 1113, 1114.     -   3. Receive the file, uncompress it and save it to disk in a well         known location (that is configurable) under a numbered sub         directory based on the current date.     -   4. Acknowledge receipt of the file, close the connection and         exit the thread.         Database Insertor Daemon—sldb

The database insertor daemon 1108, 1110, running on the Log Server 1105, 1106, does the following:

-   -   1. Looks up the latest directory in which the Log Collector         daemon 1107, 1109, is placing the log files.     -   2. When a new log file is found, checks to see if the contents         of the file needs to be added to the database. Some files like         the syslog files need not be processed.     -   3. Creates a thread for the file. The thread establishes a         connection to the database and inserts the contents of the log         file into the database.     -   4. Exit the thread.     -   5. The database insertor 1108, 1110, can also be run in         standalone mode. In this mode, sldb 1108, 1110, can be         configured to look for files starting from a specified sub         directory and insert them into the database.

Config File Format

The log daemons do not depend on the configuration file. All the information they need is hard coded or DNS based. This reduces the need to ship config files to all the servers in the network.

Command Line Options

The following command line options are supported by the daemons.

-   -   d <donedir> sets the done directory for the distributor daemon     -   r <recvdir> sets the receive directory for the collector daemon         and database insertor daemon.     -   p <port num> sets the port num for the collector or distributor         daemon     -   i <ip> sets the default ip for sending log files, for the         distributor daemon     -   m <no. of threads> maximum number of threads for the daemon     -   s run in standalone mode, not as a daemon     -   D<debug level> sets the debug option with the level specified     -   V prints the version information     -   v prints the CV S version information     -   h/? prints usage options

Apart from the above the database insertor daemon(sldb) also supports the following options:

-   -   S<ddmmhhyy> date dir from which to start inserting files,         default is current datedir     -   b<subdir num> subdir number inside the startdir to start from,         default is 0     -   e <end subdir> subdir at which to stop inserting files, default         is to keep up with the collector daemon

File Naming Conventions

Log files are named according to the following naming convention. The _ character is used as a token separator.

-   -   svc_svcst_server_location_network_ip_date_time(s)_time(us)_pid     -   svc service name (eg. http, dns, sprobe, lprobe, . . . )     -   svcst service sub type (eg. sec, min, log)     -   server server name (eg. server-1, server-2, . . . )     -   location location name (eg. sjc, bos, . . . )     -   network network name (eg. mci, uunet, . . . )     -   ip server ip (eg. 10.10.10.12, . . . )     -   time timein secs since the Epoch     -   time time in usecs     -   pid pid (process id)

Message Formats

The message format used to communicate between the log distributor daemon and the log collector daemon is described below. Each message consists of an eight byte fixed header plus a variable size payload:

Opcode (1 Byte)

The currently defined opcodes are:

Value Name 0 SLU_INVALID 1 SLU_FILE_READY 2 SLU_RECV_READY 3 SLU_FILE_DATA 4 SLU_FILE_RECD 5 SLU_ERROR Info (1 byte)

-   Contains opcode specific information.

Version Number (1 Byte)

-   The logging subsystem protocol version number

Payload Length (4 Bytes)

-   The total length of the payload data in bytes.

Payload

-   Command specific payload data field.     All the fields are in network byte order.

SLU_INVALID

-   A place holder to detect zero-filled or malformed messages.

SLU_FILE_READY

The log distributor daemon sends this message to the log collector daemon after it finds a log file and connects. The expected response from the log collector daemon is an SLU_RECV_READY. If there is a problem an SLU_ERROR is returned:

SLU_RECV_READY

The log collector daemon returns this message when it is ready to receive data after a new connect.

SLU_FILE_DATA

This message is sent when the log distributor daemon is ready to send a file to the log collector daemon after the collector daemon returns the SLU_RECV_READY Message. The payload contains the compressed file data:

SLU_FILE_RECD

This message is sent when the log collector deamon has successfully recd a file.

SLU_ERROR

This message is returned on any non recoverable error. The info field in the message header contains qualifying information on the error condition. The following fields are valid. The connection is reset on any error condition.

Error Handling

-   Connect failure for distributor daemon:

In case the distributor daemon is not able to establish a connection to any of the Log Servers, the number of active threads is reduced to one. This thread keeps trying to connect to the Log Server after certain time intervals. If a connection is established, the number of threads for the distributor daemon is restored back to the maximum configured value.

Local Load-Balancing and Global Load-Balancing

When load-balancing is performed within a particular POP, it is referred to as local load-balancing. Two techniques for performing local load-balancing within a particular POP shall now be explained with reference to FIG. 12A and FIG. 12B, which are block diagrams of an illustrative network according to an approach. According to the technique shown in FIG. 12A, Web browsers 1202A, 1202B, 1202C, and 1202D are operationally connected to client domain name server 1210 (“client DNS 1210”). Client DNS 1210 contains a list 1212 that associates one or more IP addresses with each of a set of host names. For example, list 1212 may associate the four IP addresses shown in FIG. 12A with the host name “www.customer.com.”

Client DNS 1210 also contains a configuration table 1214 used in determining where packets should be routed. Configuration table 1214 includes information about which routes leads to which IP addresses, priorities for routes to be used, and rules for handling routine and special cases of traffic.

When client DNS 1210 receives a request to resolve a host name entry from a Web browser, client DNS 1210 determines which IP address is associated with the host name by picking an IP address from list 1212 that is associated with the host name in question. For example, if Web browser 1202B transmits a request to resolve the host name of “www.customer.com” to client DNS 1210, then client DNS 1210 will pick an IP address from list 1212 associated with the “www.customer.com” host name.

In an embodiment, client DNS 1210 picks IP addresses from list 1212 in a round-robin sequence, i.e., once a particular IP address associated with a particular host name in list 1212 is picked, the next IP address associated with the particular host name in list 1212 is the next IP address to be picked by client DNS 1210. For example, IP addresses 1.2.3.1, 1.2.3.2, 1.2.3.3, and 1.2.3.4 are associated with the “www.customer.com” host name. Initially, client DNS 1210 may pick IP address 1.2.3.1 after receiving a first request to resolve a host name entry for “www.customer.com,” then pick IP address 1.2.3.2 after receiving a second request to resolve a host name entry for “www.customer.com,” then pick IP address 1.2.3.3 after receiving a third request to resolve a host name entry for “www.customer.com,” then pick IP address 1.2.3.4 after receiving a fourth request to resolve a host name entry for “www.customer.com,” and then pick IP address 1.2.3.1 after receiving a fifth request to resolve a host name entry for “www.customer.com.” In this way, client DNS 1210 distributes content requests over all the IP addresses contained in list 1212 for a particular host name, thereby reducing the demand on any particular Web server.

A second technique for performing local load-balancing within a particular POP is shown in FIG. 12B. After client DNS 1260 of FIG. 12B receives a request to resolve a host name entry from a Web browser, client DNS 1260 issues a domain name resolution request to root domain name server 1262 to determine an IP address associated with the host name of the request. For example, if Web browser 1202C transmits a request to resolve a host name entry for “www.customer.com” to client DNS 1260, then client DNS 1260 issues a domain name resolution request for the host name “www.customer.com” to root domain name server 1262. The root domain name server 1262 responds to the domain name resolution request by informing client domain name server 1260 that the IP address for that host name is the IP address of load balancer 1270. After receiving the response from the root domain name server 1262, the client domain name server 1260 transmits the IP address of load balancer 1270 to the requesting Web browser to inform the requesting Web browser that the IP address of the host name is the IP address of load balancer 1270.

Load balancer 1270 is a functional component that dispatching HTTP requests among a group of Web servers using load balancing techniques. For example, load balancer 1270 may dispatch HTPP requests received from Web browsers between 1280A, 1280B, 1280C, and 1280D. Load balancer 1270 may assign a particular Web server to a received HTTP request based on a variety of mechanisms, e.g., round-robin or dynamically determining which Web server has the most bandwidth.

While both of the techniques described above with reference to FIG. 12A and FIG. 12B advantageously perform local load-balancing within a single POP, the above techniques cannot be used for performing load-balancing across multiple POPs efficiently. As many Web sites employ multiple POPS distributed across various geographical locations, it is important to ensure efficient load-balancing across all the POPs of a Web site to minimize processing delays.

FIG. 13 is a block diagram of an illustrative network performing load-balancing across multiple POPs according to an approach. When load-balancing is performed across multiple POPs, it is referred to as global load-balancing. As shown in FIG. 13, a user of a Web browser 1302 may request and receive content from a Web site having multiple POPs. An example shall be discussed below in which a user of Web browser 1302 wishes to receive the Web page “www.customer.com/main.html,” and content for host name “www.customer.com” is supplied by two POPs, namely POP 1320 and POP 1330. POP 1320 and POP 1330 contain set of POP DNS 1322 and set of POP DNS 1332 respectively. Set of POP DNS 1322 and 1332 are a set of one or more DNS servers that service the POP in which they reside.

In response to user input, Web browser 1302 transmits a request to resolve the host name entry of “www.customer.com” to client DNS server 1310. The client DNS server 1310 processes the request to resolve the host name entry by communicating with the set of POP DNS servers 1322 and the set of POP DNS servers 1332. The set of POP DNS servers 1322 and the set of POP DNS servers 1332, in turn, communicate with probes 1324 and 1334 respectively. Probes 1324 and 1334 are functional components that are capable of determining how far away a requesting Web browser is from the POP in which the probe is located. A probe may make the determination of how far away a requesting Web browser is from the POP in which the probe is located using a variety of mechanisms, e.g., (a) sending a request for a response communication to the Web browser 1302, and analyzing how long it takes for the response communication to arrive, and (b) determining how many hops exists between Web browser 1302 and the POP in which the probe is located.

For example, probe 1324 may determine that 10 hops exist between POP 1320 and Web browser 1302, and probe 1334 may determine that only 1 hop exists between POP 1320 and Web browser 1302. After a probe in a particular POP determines how far away Web browser 1302 is, the probe notifies the set of POP DNS servers located at the particular POP. For example, probe 1324 notifies the set of POP DNS servers 1322 that there are 10 hops between POP 1320 and Web browser 1302, and probe 1334 notifies the set of POP DNS servers 1332 that there is one hop between POP 1330 and Web browser 1302. In addition to proximity information, the probe may also notify the set of POP DNS servers about the availability of Web servers at the POP.

The set of POP DNS servers 1322 and the set of POP DNS servers 1332 each inform client DNS server 1310 with the information obtained by the probes. Thereafter, client DNS server 1310 uses the probe information to determine which POP (“the selected POP”) should provide service to Web browser 1302. After the client DNS 1310 determines which POP should provide service to Web browser 1302, the client DNS server 1310 transmits a domain name resolution request to the selected POP. After receiving the response, from the selected POP, to the domain name resolution request, client DNS server 1310 may thereafter send the resolved IP address of one of the POP DNS servers in the selected POP to Web browser 1302 to enable the Web browser 1302 to obtain the requested content from the selected POP.

This approach for load-balancing may require a significant amount of processing at each POP. For example, unless an IP address for a particular domain name is cached at the client DNS 1310, each time Web browser 1302 transmits a request to resolve a host name entry to client DNS 1310, client DNS 1310 must contact each of the set of POP DNS servers, and wait for each probe in each POP to determine how far away Web browser 1302 is from the POP in which the probe is located.

Architecture Overview of an Embodiment Performing Both Local and Global Load-Balancing

Embodiments of the invention perform both global load-balancing and local load-balancing. Specifically, embodiments of the invention advantageously allow domain name resolution requests to be load balanced across all point of presences (POPs) of the system. When the client DNS sends a domain name resolution request to a particular POP DNS server, an Internet router routes the request to a POP DNS server that is closest in network proximity across all POPs of the system. Once that POP DNS server receives the domain name resolution request, the POP DNS server performs local load balancing techniques to dynamically select the appropriate Web server (“the selected Web server”) and to use the selected Web server's IP address for resolving the domain name resolution request.

FIG. 14 is a block diagram of a system 1400 according to an embodiment of the invention. In an embodiment, system 1400 includes one or more Web browsers, a client DNS, and two or more POPs. Each of the components of system 1400, in addition to the above description, shall be discussed in further detail below.

A Web browser, such as Web browser 1402, refers to any functional component that is capable of requesting a Web page or any content that is identifiable by a URL. Non-limiting, illustrative embodiments of Web browser 1402 include Internet Explorer available from Microsoft Corporation. While only Web browser 1402 is depicted in FIG. 14 for ease of explanation, other embodiments of the invention may include any number of Web browsers. Typical embodiments include a large number and variety of Web browsers.

A client DNS, such as client DNS 1404, refers to any functional component that is capable of issuing domain name resolution requests and responding to a request to resolve a host name entry.

Communications link 1410 may be implemented by any medium or mechanism that provides for the exchange of data between Web browser 1402 and client DNS 1404. Communications link 1412 may be implemented by any medium or mechanism that provides for the exchange of data between Web browser 1402 and a POP, such as POP 1420, 1430, and 1440. Examples of communications links 1410 and 1412 include, without limitation, a network such as a Local Area Network (LAN), Wide Area Network (WAN), Ethernet or the Internet, or one or more terrestrial, satellite or wireless links.

POP 1420, 1430, and 1440 each refer to a point of presence. A Web site operator may operate several POPs, each operating in a different geographical location, to minimize the distance over a network between a Web browser requesting content from the Web site and the Web server providing the Web site content to the requesting Web browser. For example, POP 1420 may be located in San Jose, Calif., POP 1430 may be located in New York, N.Y., and POP 1440 may be located in London, England. While only POP 1420, 1430, and 1440 are shown in FIG. 14, system 1400 may include any number of POPS. The invention's architecture can simply add more DNS and content servers to provide more capacity without scalability constraints.

Each POP contains a set of POP DNS servers, such as set of POP DNS servers 1422, 1432, and 1442. A set of POP DNS servers refers to one or more domain name servers (individually referred to as a “POP DNS server”) that operate as a functional unit. A set of POP DNS servers containing more than one POP DNS server is advantageous for local load-balancing purposes. For example, a set of POP DNS servers may be composed of three POP DNS servers, and if a single POP DNS server in the set of POP DNS servers becomes inoperable, then two other POP DNS servers are still able to function. In an embodiment, the POP DNS servers in a set of POP DNS servers can be assigned the same IP address as any other POP DNS servers in a set of POP DNS servers in system 1400. Additionally, as described in greater detail below, a particular POP DNS server of a set of POP DNS servers may be assigned multiple IP addresses. As explained in further detail below, a set of POP DNS servers determines which Web server should be used to resolve a domain name resolution request received by the set of POP DNS servers. A POP DNS server may be implemented by an SPD, described above.

Each POP also contains one or more Web servers. For example, POP 1420 contains Web servers 1424A, 1424B, 1424C, and 1424D, POP 1430 contains Web servers 1434A, 1434B, 1434C, and 1434D, and POP 1440 contains Web servers 1444A, 1444B, 1444C, and 1444D. A Web server supplies requested content to a Web browser. While each POP of system 1400 is shown as having four Web servers, each POP of system 1400 may have any number of Web servers.

Each POP also contains one or more probes. For example, POP 1420 contains probe 1426, POP 1430 contains probe 1436, and POP 1440 contains probe 1446. A probe is any functional component that is capable of determining whether a Web server is operational and assessing the load on the Web server. POP DNS servers 1422 may use a probe 1426 to determine how much capacity of a particular Web server in POP 1420 currently has to assist the dynamic local load-balancing performed by POP DNS servers 1422. As embodiments of the invention advantageously assign the same anycast IP address to multiple POP DNS servers across a plurality of POPs, the probes of a POP need not perform all the functionality of the probes described above in reference to other embodiments not assigning the same IP address to multiple POP DNS servers, e.g., the function of determining how many hops exist between Web browser 1402 and a particular POP need not be performed by embodiments of the invention using anycast IP routing.

Load-Balancing using IP Anycast Routing

FIG. 15 is a flowchart illustrating the functional steps of a Web browser requesting content according to an embodiment of the invention. By performing the steps of FIG. 15, global load-balancing may be performed across all POPs supplying content for a Web site by determining which POP should service a content request based on proximity and availability. In addition, by performing the steps of FIG. 15, local load-balancing may be performed at a particular POP by dynamically determining which Web server of the particular POP should service the content request based on availability.

The steps of FIG. 15 shall be explained below with reference to an example wherein the cache of Web browser 1402 and client DNS server 1404 are both empty. After the steps of FIG. 15 are explained, several embodiments shall be discussed wherein information may be saved in the cache of either Web browser 1402 or client DNS server 1404 to expedite processing.

Initially, in step 1510, Web browser 1402 transmits a request to resolve a host name entry to client DNS server 1404. For example, Web browser 1402 may transmit a request to resolve the host name of “www.customer.com” to client DNS server 1404 over communications link 1410. After the performance of step 1510, processing proceeds to step 1520.

In step 1520, client DNS server 1404 sends a domain name resolution request to a customer DNS server. Since the customer DNS server is configured to delegate its domain to the POP DNS as the authoritative DNS, it tells the client DNS server 1404 to contact the POP DNS IP address for resolution of the request. The client DNS server 1404 then sends the request to the POP DNS. Since multiple POPs have been assigned the same anycast IP address, an Internet router routes the request to a particular POP that is closest in network proximity. The particular POP DNS server that receives the domain name resolution request of step 1520 shall be referred to herein as the “closest” POP DNS server. As explained below, an Internet router may perform step 1520 by making use of the IPv6 anycast feature. Further information about the IPv6 anycast feature, and the IPv6 protocol in general, may be found in the RFC 2460 Internet Protocol IPv6 Specification document by the Network Working Group.

In an embodiment, the performance of step 1520 may be assisted by assigning the same anycast IP address to each POP DNS server in the set of POP DNS servers in each POP of system 1400. For example, POP DNS server 1423A, 1423B, 1433A, 1433B, 1443A, and 1443B may each be assigned the same IP address. An Internet router consults a configuration table to determine the shortest route (e.g., smallest number of hops) to the IP address assigned to each POP DNS server. The client DNS server 1404 sends a packet containing the domain name resolution request and the Internet router routes the packet to the IP address assigned to the set of POP DNS servers. As routers are configured to transmit packets to an IP address using the shortest available route, the packet containing the domain name resolution request will be delivered to the POP DNS server that is in closest network proximity to the client DNS server 1404.

It is advantageous for the client DNS server 1404 to only send a single packet to the IP address assigned to the set of POP DNS servers because if two or more packets were sent, then the two or more packets may be routed to different POP DNS servers. After the performance of step 1520, processing proceeds to step 1530.

In step 1530, the closest POP DNS server, which received the domain name resolution request of step 1520, dynamically resolves the domain name resolution request. For example, if POP DNS server 1433B received the packet containing the domain name resolution request of step 1520, then POP DNS server 1433B dynamically resolves the domain name resolution request in step 1530.

The domain name resolution request may be resolved by dynamically determining, based on availability information, which Web server (referred to herein as the “the selected Web server”) is best suited to serve content to the Web browser associated with the domain name resolution request. Once the selected Web server is identified, the domain name resolution request is resolved by determining an IP address of the selected Web server. Local load-balancing techniques may be employed to dynamically determine which Web server is best suited to serve content to the Web browser associated with the domain name resolution request.

Probes may assist the dynamic resolution of the domain name resolution request by providing, to each POP DNS server in the same POP as the probe, information about availability of each Web server in the POP. For example, probe 1436 may assist the dynamic resolution of the domain name resolution request by providing to each POP DNS server 1433A and POP DNS server 1433B information about availability of Web server 1434A, 1434B, 1434C, and 1434D. The information that probe 1436 provides to POP DNS server 1433A and POP DNS server 1433B may include service availability information about each Web server in POP 1430, and information about the load on each Web server in POP 1430. In addition, probe 1436 may inform POP DNS server 1433A and POP DNS server 1433B that a Web server in POP 1430 is inoperable.

In one embodiment, each probe in a POP stores data that identifies one or more POPs in system 1400 that are in close network proximity, i.e., they are neighboring POPs. In such an environment, each probe in a POP may also provide information to POP DNS servers in a neighboring POP in addition to providing information to the POP DNS servers of their own POP. For example, if POP 1440 is a neighboring POP to POP 1430, probe 1436 may also provide information to POP DNS server 1443A and 1443B in addition to providing information to POP DNS servers 1433A and 1433B. As described in further detail below, it is advantageous for a probe in a first POP to provide information to a neighboring POP, e.g., in the case where traffic is directed from the first POP to the neighboring POP, POP DNS servers in the neighboring POP have the benefit of the current operational status of Web servers in the first POP.

In one embodiment, the probes notify neighboring POPs of Web server availability in the POP. This allows a POP to know when a neighboring POP is already overloaded before attempting to direct traffic to the neighboring POP. The POP can then direct traffic to another neighboring POP, thus avoiding forcing the overloaded neighboring POP to redirect to another neighboring POP. This also helps prevent possibly causing a chain reaction of ping-ponging traffic between overloaded POPs or from an overloaded POP back to the originating POP.

In another embodiment, probes can forward load information of the Web servers in the POP to neighboring POPs. This allows POPs to load balance traffic directly to Web servers in neighboring POPs. After the performance of step 1530, processing proceeds to step 1540.

In step 1540, the POP DNS server that resolved the IP address in step 1530 transmits the resolved IP address to the client DNS 1404 server. After the processing of step 1540, processing proceeds to step 1550.

In step 1550, the client DNS server 1404 transmits the resolved IP address to Web browser 1402. After the processing of step 1550, processing proceeds to step 1560.

In step 1560, Web browser 1402 contacts the selected Web server using the resolved IP address received in step 1550. Both global and local load-balancing techniques were employed in performing the steps of FIG. 15. Thus, no other Web server in the system 1400 should be able to supply the Web browser 1402 with requested content as efficiently, given the current load on each Web server in each POP, as the selected Web server. Advantageously, the user experience provided by Web browser 1402 is enhanced because of the quality service provided by the selected Web server to the Web browser 1402.

In an embodiment of the invention, caching may be used to expedite processing. For example, in step 1550, the client DNS server 1404 may store a copy of the resolved IP address in the cache of the client DNS server 1404. Thereafter, anytime the client DNS server 1404 receives a subsequent domain name resolution request, from any Web browser, for the domain name associated with the resolved IP address stored in the cache of the client DNS server 1404, the client DNS server 1404 can service the subsequent domain name resolution request using the IP address stored in its cache. To ensure that the information in the cache of the client DNS server 1404 is as valid as possible, any resolved IP address stored in the cache of the client DNS server 1404 may be associated with an expiration time parameter wherein after an expiration of time indicated by the expiration time parameter, the resolved IP address is deleted from the cache.

In another embodiment, after the performance of step 1550, once Web browser 1402 receives the resolved IP address, the Web browser 1402 may store the resolved IP address in its own cache. Thereafter, anytime that Web browser 1402 needs to request content from the domain name associated with the resolved IP address, Web browser 1402 may use the resolved IP address, associated with the domain name of the requested content, which is stored in the cache of Web browser 1402. Information stored in the cache of Web browser 1402 may also be associated with an expiration time parameter.

Techniques have been described above wherein a plurality of domain name servers are assigned an anycast IP address. However, as other network components, such as a load balancer, may receive traffic at a POP, other embodiments of the invention may be employed where other network components, other than a domain name server, are assigned an anycast IP address. For example, an embodiment of the invention may also assign a load balancer an anycast IP address. Consequently, embodiments of the invention may assign any type of network component an anycast IP address, and are not limited to the use of an assigned anycast IP address to just a domain name server.

Handling Traffic Bursts at a Pop

FIG. 16 is a flowchart illustrating the functional steps of handling traffic bursts according to an embodiment of the invention. By performing the functional steps of FIG.15, embodiments of the invention may advantageously perform global traffic management, using global and local load-balancing techniques, in normal traffic patterns. However, for a variety of reasons, large bursts of traffic in a particular geographical region may be experienced. In such a case, Web servers of a POP serving the particular geographical region may become saturated. Accordingly, embodiments of the invention, discussed below with reference to FIG. 16, handle traffic bursts capable of overloading all Web servers of a particular POP.

Initially, in step 1610, a determination is made as to whether a configurable capacity threshold has been exceeded for all Web servers in a POP. In an embodiment, a probe may make the determination of step 1610, such as probe 1426. In such an embodiment, the probe monitors each Web server in the POP in which the probe is located to determine if any Web server in the POP exceeds the configurable capacity threshold.

In an embodiment, the configurable capacity threshold is a maximum level of capacity that a particular Web server may experience before additional requests, that normally would be routed to the particular Web server, are redirected to another Web server. For example, in an embodiment, the configurable capacity threshold may be set to 80% capacity for all Web servers in a POP; consequently, once all Web servers in a POP experience a load that is more than 80% of all the Web server's capacity, the configurable capacity threshold has been exceeded. The configurable capacity threshold may be configured by an administrator of system 1400, and may be expressed in a variety of metrics, such as a percent of total capacity, an amount of individual simultaneous requests, and an amount of incoming packets.

Once it has been determined that the configurable capacity threshold has been exceeded, processing proceeds to step 1620.

In step 1620, any subsequent domain name resolution requests are redirected by POP DNS servers in the POP to a neighboring POP until the configurable capacity threshold associated with the POP is no longer exceeded. The entity that performs step 1610 informs each set of POP DNS servers in the POP where the configurable capacity threshold has been exceeded. For example, if probe 1426 performs step 1610 and determines that all Web servers in POP 1420 have exceeded the configurable capacity threshold, then probe 1426 informs the set of POP DNS servers 1422 that all Web servers in POP 1420 have exceeded the configurable capacity threshold.

Any subsequent domain name resolution requests received by the set of POP DNS servers 1422 are redirected to a neighboring POP until the configurable capacity threshold of POP 1420 is no longer exceeded. To illustrate, if in step 1610 probe 1426 determines that the configurable capacity threshold of Web servers 1424A, 1424B, 1424C, and 1424D have been exceeded, then in step 1620, the set of POP DNS servers 1422 consult data that identifies one or more POPs that are in close network proximity to POP 1420, e.g., POP 1430. Thereafter, any subsequent domain name resolution requests received by a POP DNS server in POP 1420 are redirected to a POP DNS server in the neighboring POP.

As each POP DNS server in the set of POP DNS servers 1422 and the set of POP DNS servers 1432 are assigned the same IP address, that IP address cannot be used to redirect packets. Consequently, each POP DNS server in each POP of system 1400 also is assigned at least one other IP address that is unique to the POP in which the set of POP DNS servers reside in, e.g., each of the set of POP DNS servers 1432 in POP 1430 are assigned an IP address that is not the same as the IP address assigned to each of the set of POP DNS servers 1422 in POP 1420. A POP DNS server uses the unique real IP address of a POP DNS server to redirect traffic to the POP DNS servers in the neighboring POP.

Once the domain name resolution request is received at the neighboring POP, the POP DNS server that received the domain name resolution requests resolves the domain name resolution request using the address of a Web server at the neighboring POP. For example, if, in step 1620, POP DNS server 1423A sends a domain name resolution request to POP DNS server 1433A using the alternate IP address of POP DNS server 1433A, then POP DNS server 1433A resolves the domain name resolution request at the neighboring POP using local load-balancing techniques and sends the address of the resolved Web server to the requester.

After the configurable capacity threshold is no longer exceeded at a POP, subsequent domain name resolution requests no longer need to be forwarded to a neighboring POP. For example, assume that in step 1610 probe 1426 determines that all Web servers in POP 1420 exceed the configurable capacity threshold. If, at a later point in time, probe 1426 determines that not all Web servers in POP 1420 exceed the configurable capacity threshold, then the set of POP DNS servers 1422 are notified by probe 1426 that not all Web servers in POP 1420 exceed the configurable capacity threshold. Subsequently received domain name resolution requests need not be forwarded to another POP unless and until all Web servers in POP 1420 exceed the configurable capacity threshold again.

As explained in further detail below, in some embodiments, step 1620 is not performed if a condition, such as the detection of a denial of service (DOS) attack, is satisfied.

In one embodiment, the POP DNS has the knowledge gained from probes at neighboring POPs that a POP is overloaded. If all neighboring POPs are overloaded, the POP can stop all redirection of traffic and fail to respond to any requests. This allows the neighboring POPs to recover without having other neighboring POPs creating problems by directing traffic to other neighboring POPs and saturating the network. This works very well with DOS attacks described below.

Promoting Security

In a denial of service (DOS) attack, a component, such as a router or server, is flooded with unwanted messages in an attempt to shut the component down. A DOS attack typically affects the POP of a Web site that is closest in network proximity to the origin of the DOS attack, as packets from the origin of the DOS attack are typically directed to the same POP. Advantageously, embodiments of the invention minimize the impact of DOS attacks by limiting the exposure of Web servers of the system 1400. As explained above, when a particular POP experiences a traffic burst, the particular POP redirects subsequent requests to a neighboring POP. Thus, all redirected traffic remains within the neighboring POPs and other POPs of system 1430 that are not neighboring POPs are not exposed to the DOS attack.

Alternatively, if a DOS attack is detected, then step 1620 is not performed. Advantageously, if a DOS attack is directed against a particular POP of system 1400, then by not performing step 1620, the DOS attack is kept local (and thereby contained) to the particular POP experiencing the DOS attack, and other POPs of system 1400 (including the neighboring POPs) are not exposed. Thus, the other POPs of system 1400 that are not exposed are still able to serve content to requesters. Once the DOS attack is determined to no longer be a threat (e.g., the POP is no longer being flooded with messages), the POP returns back to its normal operations.

In one embodiment, neighboring POPs can be grouped into regions where a set of POPs is in a designated region. A system administrator can designate which POPs belong to a region. Each POP receives configuration information telling it what region it belongs to and which POPs are its neighbors. As discussed above, a POP can receive load information for its neighboring POPs from probes in those POPs. If a DOS attack occurs, a POP will see that all of the POPs in its region are overloaded and can stop redirecting traffic to other POPs in the region. This allows the system to stop the spread of a DOS attack beyond a specified area. The designation of regions also allows the system to expand a group of neighboring POPs beyond a geographical boundary and into logical boundaries. Regions can be exclusive or overlapping. Regions can overlap to a certain degree where the overlap between regions does not create a scenario where the interconnections create one large region.

Handling Various Failure Scenarios

Embodiments of the invention also are configured to automatically recover from the failure of one or more components of the system and are fault-tolerant and highly available. The manner in which system 1400 recovers from a failure depends on which component(s) in system 1400 failed. Several embodiments of the invention shall be discussed below involving the failure of one or more components of system 1400. The invention eliminates the possibility of traffic oscillating between POPs.

Handling a Single Web Server Failure

Embodiments of the invention may recover from the failure of a single Web server at a POP. In one embodiment, each probe of a POP periodically determines if each Web server in the POP is operational. If a probe determines that a particular Web server is not operational, then the probe informs the set of POP DNS servers at the POP that the particular Web server is not operational. For example, if Web server 1424B becomes inoperable in POP 1420, probe 1426 determines that Web server 1424B is inoperable, and notifies the set of POP DNS servers 1422 in POP 1420. After the set of POP DNS servers 1422 are informed that a particular Web server in POP 1420 is inoperable, the set of POP DNS servers 1422 will exclude the inoperable Web server from consideration when resolving domain name resolution requests until the particular Web server becomes operable.

In another embodiment, a local load balancer may be employed. FIG. 17 is a block diagram of a POP 1720 configured to recover using a local load balancer 1722 according to an embodiment of the invention. POP DNS server 1724 resolves domain name resolution requests, sent by client DNS server 1710, using the IP address of load balancer 1722. Thus, Web browser 1702 will contact load balancer 1722 using the IP address of load balancer 1722 in the performance of step 1560.

When load balancer 1722 receives a request for content from a Web browser, load balancer transmits the request to a Web server operationally connected to the load balancer using local load balancing techniques. If a particular Web server, such as Web server 1724C, becomes inoperable, then load balancer 1722 is configured to automatically dispatch traffic to operational Web servers operationally connected to load balancer 1722. Thus, Web server 1724C will not be dispatched any traffic by load balancer 1722 as Web server 1724C is inoperable. Having load balancer 1722 in POP 1720 makes it unnecessary for a probe to be used by POP DNS server 1724, as load balancer 1722 is configured to monitor the Web servers of POP 1720. The load balancer 1722 my use a probe for its determination of Web server loads as described above. However, load balancer 1722 may function as a bottleneck, thereby slowing down processing, if the amount of traffic received at load balancer 1722 exceeds the amount of traffic that the load balancer 1722 can process.

Handling the Failure of all the Web Servers of a Pop

Embodiments of the invention may recover from the failure of all the Web servers of a POP. According to an embodiment, if a probe in a particular POP determines that all Web servers have become inoperable in a particular POP, then the set of POP DNS servers of the POP having all inoperable Web servers will redirect any subsequently received domain name resolution requests to the set of POP DNS servers in neighboring POPs.

For example, if Web servers 1424A, 1424B, 1424C, and 1424D become inoperable, then probe 1426 will determine that Web servers 1424A, 1424B, 1424C, and 1424D are inoperable. Thereafter, probe 1426 will inform the set of POP DNS servers 1422 that Web servers 1424A, 1424B, 1424C, and 1424D are inoperable. The set of POP DNS servers 1422 will then redirect any subsequent domain name resolution request received by the set of POP DNS servers 1422 to the set of POP DNS servers 1432 in POP 1430 if POP 1430 is a neighbor of POP 1420.

Handling the Failure of a Single Pop DNS Server

Embodiments of the invention may recover from the failure of a single POP DNS server in the set of POP DNS servers in a particular POP. For example, assume that in POP 1420, the set of POP DNS servers 1422 comprises two POP DNS servers, namely POP DNS server 1423A and 1423B. Each of the set of POP DNS servers 1422 are assigned the same IP address.

If POP DNS server 1423A becomes inoperable, probe 1426 will detect that POP DNS server 1423A is inoperable, and notifies the router that is local to POP 1420 that POP DNS server 1423A is inoperable. Probe 1426 may also inform an administrator of system 1400 that POP DNS server 1423A is inoperable, so that the administrator may restart POP DNS server 1423A. Client DNS server 1404 may still communicate with POP 1420 using POP DNS server 1423B, even though POP DNS server 1423A is inoperable. The local router will route the client DNS server requests around POP DNS server 1423A. As POP DNS servers 1423A and 1423B are each assigned the same IP address, client DNS server 1404 may still continue to communicate with POP 1420 using the same IP address, except that traffic routed to POP 1420 will exclusively be handled by POP DNS server 1423B.

Handling the Failure of all of the Pop DNS Servers at a Pop

Embodiments of the invention may recover from the failure of all of the POP DNS servers of a POP by assigning multiple anycast IP addresses to each POP DNS server in the system. For example, assume that all of the set of POP DNS servers 1422 became inoperable in POP 1420. As previously mentioned, each POP DNS server in system 1400 is assigned the same IP address, which shall be referred to hereafter as “IP address A.” Additionally, a first portion of the POP DNS servers in system 1400 are assigned a second IP address (referred to hereafter as “IP address B”), e.g., every DNS server in all POPs with odd numbered addresses are assigned IP address B. Then a second portion of the POP DNS servers in system 1400 are assigned a third IP address (referred to hereafter as “IP address C”), e.g., every DNS server in all POPs with even numbered addresses are assigned IP address C. As shall be made evident in the below discussion, it is advantageous for both the first portion and the second portion to be each comprised, as best possible, with half of the POP DNS servers in system 1400.

FIG. 18 is a block diagram of a system 1800 configured to recover from the failure of all POP DNS servers at a POP according to an embodiment of the invention. As shown in FIG. 18, each POP DNS server in POP 1820, 1830, and 1840 are assigned IP address A. However, POP DNS servers in POP 1820 and 1840 are also assigned to IP address B, and POP DNS servers in POP 1830 are also assigned to IP address C.

If all the POP DNS servers in a POP become inoperable, when client DNS server 1804 attempts to send a domain name resolution request to IP address A, the client DNS server 1804 will either experience a time-out if the request is routed to the POP with all POP DNS servers down, or experience a normal reply when the request is routed to an operable POP. A time-out is an expiration of a certain amount of time without receiving a response that indicates that the packet that was sent to a specific IP address arrived. When client DNS server 1804 experiences a time-out after sending a domain name resolution request to an IP address, the client DNS server 1804 must decide where to send the request. The client DNS server 1804 can round-robin through the remaining anycast IP addresses. Thus, after the client DNS server 1804 experiences the time-out for sending the domain name resolution request to IP address A, the client DNS server 1804 sends a domain name resolution request to IP address B.

If the POP DNS servers of the inoperable POP were not assigned IP address B, then the client DNS server 1804 will be able to send the domain name resolution request to the POP DNS server that is closest in network proximity (according to the Internet router) that is assigned IP address B. However, if the POP DNS servers of the inoperable POP were assigned IP address B, then the client DNS server 1804 will experience another time-out in response to sending a domain name resolution request to IP address B. Therefore, when the client DNS server 1804 experiences another time-out in response to sending the domain name resolution request to IP address B, the client DNS server 1804 sends another domain name resolution request to IP address C.

As IP addresses B and C refer to different groups of POP DNS servers, one of the groups of POP DNS servers referred to by IP address B and C will represent a group of POP DNS servers that does not include the set of POP DNS servers that became inoperable. For example, if client DNS server 1804 transmitted a domain name resolution request to IP address C, then one of the POP DNS servers in POP 1830 will handle the domain name resolution request.

In this way, even when all of the POP DNS servers at a particular POP become inoperable, the client DNS server 1804 will be able to send domain name resolution requests to other POPs using IP address B and IP address C.

Any number of alternate IP addresses may be used, as only additional IP addresses B and C were discussed above for ease of explanation. Consequently, embodiments of the invention may use any number of alternate IP addresses to recover from the failure of a POP.

Handling the Failure of an Entire Pop

Embodiments of the invention may recover from the failure of an entire POP. When an entire POP becomes inoperable or inaccessible, Internet routers will eventually determine that the POP is inaccessible. The Internet routers will avoid routing traffic to the POP that is inaccessible, and will route any future domain name resolution requests to the POP that is closest in network proximity to the inaccessible POP. Thus, if one POP of a group of POPs becomes inoperable, then subsequent domain name resolution requests will be routed to the operable POP that is closest in network proximity to the sender of the domain name resolution request.

However, it may take the Internet routers a while before they discover the inoperable POP. The invention provides a method for routing around the inoperable POP during that time. As shown in FIG. 18, if the client DNS server 1804 is informed that a particular POP, such as POP 1820, is inaccessible, then client DNS server 1804 may use the above described technique of transmitting subsequent domain name resolution requests using IP address B and IP address C to ensure that the domain name resolution request is received by an operable POP.

Implementing Mechanisms

The Web server, POP DNS server, client DNS server, and probe may each be implemented on a computer system. FIG. 19 is a block diagram that illustrates a computer system 1900 upon which an embodiment of the invention may be implemented. Computer system 1900 includes a bus 1902 or other communication mechanism for communicating information, and a processor 1904 coupled with bus 1902 for processing information. Computer system 1900 also includes a main memory 1906, such as a random access memory (RAM) or other dynamic storage device, coupled to bus 1902 for storing information and instructions to be executed by processor 1904. Main memory 1906 also may be used for storing temporary variables or other intermediate information during execution of instructions to be executed by processor 1904. Computer system 1900 further includes a read only memory (ROM) 1908 or other static storage device coupled to bus 1902 for storing static information and instructions for processor 1904. A storage device 1910, such as a magnetic disk or optical disk, is provided and coupled to bus 1902 for storing information and instructions.

Computer system 1900 may be coupled via bus 1902 to a display 1912, such as a cathode ray tube (CRT), for displaying information to a computer user. An input device 1914, including alphanumeric and other keys, is coupled to bus 1902 for communicating information and command selections to processor 1904. Another type of user input device is cursor control 1916, such as a mouse, a trackball, or cursor direction keys for communicating direction information and command selections to processor 1904 and for controlling cursor movement on display 1912. This input device typically has two degrees of freedom in two axes, a first axis (e.g., x) and a second axis (e.g., y), that allows the device to specify positions in a plane.

The invention is related to the use of computer system 1900 for implementing the techniques described herein. According to one embodiment of the invention, those techniques are performed by computer system 1900 in response to processor 1904 executing one or more sequences of one or more instructions contained in main memory 1906. Such instructions may be read into main memory 1906 from another machine-readable medium, such as storage device 1910. Execution of the sequences of instructions contained in main memory 1906 causes processor 1904 to perform the process steps described herein. In alternative embodiments, hard-wired circuitry may be used in place of or in combination with software instructions to implement the invention. Thus, embodiments of the invention are not limited to any specific combination of hardware circuitry and software.

The term “machine-readable medium” as used herein refers to any medium that participates in providing data that causes a machine to operation in a specific fashion. In an embodiment implemented using computer system 1900, various machine-readable media are involved, for example, in providing instructions to processor 1904 for execution. Such a medium may take many forms, including but not limited to, non-volatile media, volatile media, and transmission media. Non-volatile media includes, for example, optical or magnetic disks, such as storage device 1910. Volatile media includes dynamic memory, such as main memory 1906. Transmission media includes coaxial cables, copper wire and fiber optics, including the wires that comprise bus 1902. Transmission media can also take the form of acoustic or light waves, such as those generated during radio-wave and infra-red data communications.

Common forms of machine-readable media include, for example, a floppy disk, a flexible disk, hard disk, magnetic tape, or any other magnetic medium, a CD-ROM, any other optical medium, punchcards, papertape, any other physical medium with patterns of holes, a RAM, a PROM, and EPROM, a FLASH-EPROM, any other memory chip or cartridge, a carrier wave as described hereinafter, or any other medium from which a computer can read.

Various forms of machine-readable media may be involved in carrying one or more sequences of one or more instructions to processor 1904 for execution. For example, the instructions may initially be carried on a magnetic disk of a remote computer. The remote computer can load the instructions into its dynamic memory and send the instructions over a telephone line using a modem. A modem local to computer system 1900 can receive the data on the telephone line and use an infra-red transmitter to convert the data to an infra-red signal. An infra-red detector can receive the data carried in the infra-red signal and appropriate circuitry can place the data on bus 1902. Bus 1902 carries the data to main memory 1906, from which processor 1904 retrieves and executes the instructions. The instructions received by main memory 1906 may optionally be stored on storage device 1910 either before or after execution by processor 1904.

Computer system 1900 also includes a communication interface 1918 coupled to bus 1902. Communication interface 1918 provides a two-way data communication coupling to a network link 1920 that is connected to a local network 1922. For example, communication interface 1918 may be an integrated services digital network (ISDN) card or a modem to provide a data communication connection to a corresponding type of telephone line. As another example, communication interface 1918 may be a local area network (LAN) card to provide a data communication connection to a compatible LAN. Wireless links may also be implemented. In any such implementation, communication interface 1918 sends and receives electrical, electromagnetic or optical signals that carry digital data streams representing various types of information.

Network link 1920 typically provides data communication through one or more networks to other data devices. For example, network link 1920 may provide a connection through local network 1922 to a host computer 1924 or to data equipment operated by an Internet Service Provider (ISP) 1926. ISP 1926 in turn provides data communication services through the world wide packet data communication network now commonly referred to as the “Internet” 1928. Local network 1922 and Internet 1928 both use electrical, electromagnetic or optical signals that carry digital data streams. The signals through the various networks and the signals on network link 1920 and through communication interface 1918, which carry the digital data to and from computer system 1900, are exemplary forms of carrier waves transporting the information.

Computer system 1900 can send messages and receive data, including program code, through the network(s), network link 1920 and communication interface 1918. In the Internet example, a server 1930 might transmit a requested code for an application program through Internet 1928, ISP 1926, local network 1922 and communication interface 1918.

The received code may be executed by processor 1904 as it is received, and/or stored in storage device 1910, or other non-volatile storage for later execution. In this manner, computer system 1900 may obtain application code in the form of a carrier wave.

In the foregoing specification, embodiments of the invention have been described with reference to numerous specific details that may vary from implementation to implementation. Thus, the sole and exclusive indicator of what is the invention, and is intended by the applicants to be the invention, is the set of claims that issue from this application, in the specific form in which such claims issue, including any subsequent correction. Any definitions expressly set forth herein for terms contained in such claims shall govern the meaning of such terms as used in the claims. Hence, no limitation, element, property, feature, advantage or attribute that is not expressly recited in a claim should limit the scope of such claim in any way. The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense. 

1. A computer-implemented method for handling denial of service (DOS) attacks, comprising: storing, at a domain name service (DNS) server of a particular point of presence (POP) of a plurality of POPs, neighbor data that identifies one or more other POPs of said plurality of POPs as being neighboring POPs of the particular POP; wherein the particular POP comprises a plurality of Web servers; determining whether a configurable capacity threshold has been exceeded for each Web server of the plurality of Web servers; while the configurable capacity threshold is exceeded for each Web server of the plurality of Web servers in the particular POP: a first DNS server in the particular POP receiving a first DNS request; redirecting, based on the neighbor data, the first DNS request to a first DNS server in a first neighboring POP; and wherein the first DNS server in the first neighboring POP resolves the first DNS request by returning an IP address of a Web server in the first neighboring POP; while a DOS attack that negatively affects the particular POP is detected: a second DNS server in the particular POP receiving a second DNS request; determining to not redirect the second DNS request to any DNS server in any neighboring POP of the particular POP.
 2. The method of claim 1, wherein the configurable capacity threshold is a level of capacity that a Web server may experience before additional requests, that normally would be routed to the Web server, are redirected to another Web server in the plurality of Web servers.
 3. The method of claim 1, further comprising: after detecting that the DOS attack is no longer a threat to the particular POP and while the configurable capacity threshold is exceeded for each Web server of the plurality of Web servers in the particular POP: a third DNS server in the particular POP receiving a third DNS request; redirecting, based on the neighbor data, the third DNS request to a DNS server in a neighboring POP; and the DNS server in the neighboring POP resolving the third DNS request by returning an IP address of a Web server in the neighboring POP.
 4. The method of claim 1, further comprising: storing, at the particular POP, region data that identifies the particular POP and one or more of the neighboring POPs of the particular POP as belonging to the same region; wherein the region data identifies a different set of POPs than the neighbor data; wherein the region is a logical grouping of POPs not having geographical boundaries.
 5. The method of claim 4, wherein determining to not redirect the second DNS request to any DNS server in any neighboring POP includes determining to not redirect the second request while each Web server in each POP in the region is overloaded.
 6. One or more storage media storing instructions for handling denial of service (DOS) attacks, wherein execution of the instructions by one or more processors causes: storing, at a domain name service (DNS) server of a particular point of presence (POP) of a plurality of POPs, neighbor data that identifies one or more other POPs of said plurality of POPs as being neighboring POPs of the particular POP; wherein the particular POP comprises a plurality of Web servers; determining whether a configurable capacity threshold has been exceeded for each Web server of the plurality of Web servers; while the configurable capacity threshold is exceeded for each Web server of the plurality of Web servers in the particular POP: a first DNS server in the particular POP receiving a first DNS request; redirecting, based on the neighbor data, the first DNS request to a first DNS server in a first neighboring POP; and wherein the first DNS server in the first neighboring POP resolves the first DNS request by returning an IP address of a Web server in the first neighboring POP; while a DOS attack that negatively affects the particular POP is detected: a second DNS server in the particular POP receiving a second DNS request; determining to not redirect the second DNS request to any DNS server in any neighboring POP of the particular POP.
 7. The one or more storage media of claim 6, wherein the configurable capacity threshold is a level of capacity that a Web server may experience before additional requests, that normally would be routed to the Web server, are redirected to another Web server in the plurality of Web servers.
 8. The one or more storage media of claim 6, wherein the instructions, when executed by the one or more processors, further cause: after detecting that the DOS attack is no longer a threat to the particular POP and while the configurable capacity threshold is exceeded for each Web server of the plurality of Web servers in the particular POP: a third DNS server in the particular POP receiving a third DNS request; redirecting, based on the neighbor data, the third DNS request to a DNS server in a neighboring POP; and the DNS server in the neighboring POP resolving the third DNS request by returning an IP address of a Web server in the neighboring POP.
 9. The one or more storage media of claim 6, wherein the instructions, when executed by the one or more processors, further cause: storing, at the particular POP, region data that identifies the particular POP and one or more of the neighboring POPs of the particular POP as belonging to the same region; wherein the region data identifies a different set of POPs than the neighbor data; wherein the region is a logical grouping of POPs not having geographical boundaries.
 10. The one or more storage media of claim 9, wherein determining to not redirect the second DNS request to any DNS server in any neighboring POP includes determining to not redirect the second request while each Web server in each POP in the region is overloaded.
 11. An apparatus for handling denial of service (DOS) attacks, comprising: one or more processors; one or more storage media storing instructions which, when executed by the one or more processors, cause: storing, at a domain name service (DNS) server of a particular point of presence (POP) of a plurality of POPs, neighbor data that identifies one or more other POPs of said plurality of POPs as being neighboring POPs of the particular POP; wherein the particular POP comprises a plurality of Web servers; determining whether a configurable capacity threshold has been exceeded for each Web server of the plurality of Web servers; while the configurable capacity threshold is exceeded for each Web server of the plurality of Web servers in the particular POP: a first DNS server in the particular POP receiving a first DNS request; redirecting, based on the neighbor data, the first DNS request to a first DNS server in a first neighboring POP; and wherein the first DNS server in the first neighboring POP resolves the first DNS request by returning an IP address of a Web server in the first neighboring POP; while a DOS attack that negatively affects the particular POP is detected: a second DNS server in the particular POP receiving a second DNS request; determining to not redirect the second DNS request to any DNS server in any neighboring POP of the particular POP.
 12. The apparatus of claim 11, wherein the configurable capacity threshold is a level of capacity that a Web server may experience before additional requests, that normally would be routed to the Web server, are redirected to another Web server in the plurality of Web servers.
 13. The apparatus of claim 11, wherein the instructions, when executed by the one or more processors, further cause: after detecting that the DOS attack is no longer a threat to the particular POP and while the configurable capacity threshold is exceeded for each Web server of the plurality of Web servers in the particular POP: a third DNS server in the particular POP receiving a third DNS request; redirecting, based on the neighbor data, the third DNS request to a DNS server in a neighboring POP; and the DNS server in the neighboring POP resolving the third DNS request by returning an IP address of a Web server in the neighboring POP.
 14. The apparatus of claim 11, wherein the instructions, when executed by the one or more processors, further cause: storing, at the particular POP, region data that identifies the particular POP and the neighboring POPs of the particular POP as belonging to the same region; wherein the region data identifies a different set of POPs than the neighbor data; wherein the region is a logical grouping of POPs not having geographical boundaries.
 15. The apparatus of claim 14, wherein determining to not redirect the second DNS request to any DNS server in any neighboring POP includes determining to not redirect the second request while each Web server in each POP in the region is overloaded. 